[v14,23/26] c++: Implement __is_invocable built-in trait
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This patch implements built-in trait for std::is_invocable.
gcc/cp/ChangeLog:
* cp-trait.def: Define __is_invocable.
* constraint.cc (diagnose_trait_expr): Handle CPTK_IS_INVOCABLE.
* semantics.cc (trait_expr_value): Likewise.
(finish_trait_expr): Likewise.
* cp-tree.h (build_invoke): New function.
* method.cc (build_invoke): New function.
gcc/testsuite/ChangeLog:
* g++.dg/ext/has-builtin-1.C: Test existence of __is_invocable.
* g++.dg/ext/is_invocable1.C: New test.
* g++.dg/ext/is_invocable2.C: New test.
* g++.dg/ext/is_invocable3.C: New test.
* g++.dg/ext/is_invocable4.C: New test.
Signed-off-by: Ken Matsui <kmatsui@gcc.gnu.org>
---
gcc/cp/constraint.cc | 6 +
gcc/cp/cp-trait.def | 1 +
gcc/cp/cp-tree.h | 2 +
gcc/cp/method.cc | 132 +++++++++
gcc/cp/semantics.cc | 4 +
gcc/testsuite/g++.dg/ext/has-builtin-1.C | 3 +
gcc/testsuite/g++.dg/ext/is_invocable1.C | 349 +++++++++++++++++++++++
gcc/testsuite/g++.dg/ext/is_invocable2.C | 139 +++++++++
gcc/testsuite/g++.dg/ext/is_invocable3.C | 51 ++++
gcc/testsuite/g++.dg/ext/is_invocable4.C | 33 +++
10 files changed, 720 insertions(+)
create mode 100644 gcc/testsuite/g++.dg/ext/is_invocable1.C
create mode 100644 gcc/testsuite/g++.dg/ext/is_invocable2.C
create mode 100644 gcc/testsuite/g++.dg/ext/is_invocable3.C
create mode 100644 gcc/testsuite/g++.dg/ext/is_invocable4.C
Comments
On Wed, 28 Feb 2024, Ken Matsui wrote:
> This patch implements built-in trait for std::is_invocable.
>
> gcc/cp/ChangeLog:
>
> * cp-trait.def: Define __is_invocable.
> * constraint.cc (diagnose_trait_expr): Handle CPTK_IS_INVOCABLE.
> * semantics.cc (trait_expr_value): Likewise.
> (finish_trait_expr): Likewise.
> * cp-tree.h (build_invoke): New function.
> * method.cc (build_invoke): New function.
>
> gcc/testsuite/ChangeLog:
>
> * g++.dg/ext/has-builtin-1.C: Test existence of __is_invocable.
> * g++.dg/ext/is_invocable1.C: New test.
> * g++.dg/ext/is_invocable2.C: New test.
> * g++.dg/ext/is_invocable3.C: New test.
> * g++.dg/ext/is_invocable4.C: New test.
Thanks, this looks great! This generic build_invoke function could be
used for invoke_result etc as well, and it could also cache the built-up
call across __is_invocable and __is_nothrow_invocable checks on the same
arguments (which is a common pattern in the standard library). LGTM
>
> Signed-off-by: Ken Matsui <kmatsui@gcc.gnu.org>
> ---
> gcc/cp/constraint.cc | 6 +
> gcc/cp/cp-trait.def | 1 +
> gcc/cp/cp-tree.h | 2 +
> gcc/cp/method.cc | 132 +++++++++
> gcc/cp/semantics.cc | 4 +
> gcc/testsuite/g++.dg/ext/has-builtin-1.C | 3 +
> gcc/testsuite/g++.dg/ext/is_invocable1.C | 349 +++++++++++++++++++++++
> gcc/testsuite/g++.dg/ext/is_invocable2.C | 139 +++++++++
> gcc/testsuite/g++.dg/ext/is_invocable3.C | 51 ++++
> gcc/testsuite/g++.dg/ext/is_invocable4.C | 33 +++
> 10 files changed, 720 insertions(+)
> create mode 100644 gcc/testsuite/g++.dg/ext/is_invocable1.C
> create mode 100644 gcc/testsuite/g++.dg/ext/is_invocable2.C
> create mode 100644 gcc/testsuite/g++.dg/ext/is_invocable3.C
> create mode 100644 gcc/testsuite/g++.dg/ext/is_invocable4.C
>
> diff --git a/gcc/cp/constraint.cc b/gcc/cp/constraint.cc
> index 23ea66d9c12..c87b126fdb1 100644
> --- a/gcc/cp/constraint.cc
> +++ b/gcc/cp/constraint.cc
> @@ -3791,6 +3791,12 @@ diagnose_trait_expr (tree expr, tree args)
> case CPTK_IS_FUNCTION:
> inform (loc, " %qT is not a function", t1);
> break;
> + case CPTK_IS_INVOCABLE:
> + if (!t2)
> + inform (loc, " %qT is not invocable", t1);
> + else
> + inform (loc, " %qT is not invocable by %qE", t1, t2);
> + break;
> case CPTK_IS_LAYOUT_COMPATIBLE:
> inform (loc, " %qT is not layout compatible with %qT", t1, t2);
> break;
> diff --git a/gcc/cp/cp-trait.def b/gcc/cp/cp-trait.def
> index 85056c8140b..6cb2b55f4ea 100644
> --- a/gcc/cp/cp-trait.def
> +++ b/gcc/cp/cp-trait.def
> @@ -75,6 +75,7 @@ DEFTRAIT_EXPR (IS_EMPTY, "__is_empty", 1)
> DEFTRAIT_EXPR (IS_ENUM, "__is_enum", 1)
> DEFTRAIT_EXPR (IS_FINAL, "__is_final", 1)
> DEFTRAIT_EXPR (IS_FUNCTION, "__is_function", 1)
> +DEFTRAIT_EXPR (IS_INVOCABLE, "__is_invocable", -1)
> DEFTRAIT_EXPR (IS_LAYOUT_COMPATIBLE, "__is_layout_compatible", 2)
> DEFTRAIT_EXPR (IS_LITERAL_TYPE, "__is_literal_type", 1)
> DEFTRAIT_EXPR (IS_MEMBER_FUNCTION_POINTER, "__is_member_function_pointer", 1)
> diff --git a/gcc/cp/cp-tree.h b/gcc/cp/cp-tree.h
> index 334c11396c2..261d3a71faa 100644
> --- a/gcc/cp/cp-tree.h
> +++ b/gcc/cp/cp-tree.h
> @@ -7334,6 +7334,8 @@ extern tree get_copy_assign (tree);
> extern tree get_default_ctor (tree);
> extern tree get_dtor (tree, tsubst_flags_t);
> extern tree build_stub_object (tree);
> +extern tree build_invoke (tree, const_tree,
> + tsubst_flags_t);
> extern tree strip_inheriting_ctors (tree);
> extern tree inherited_ctor_binfo (tree);
> extern bool base_ctor_omit_inherited_parms (tree);
> diff --git a/gcc/cp/method.cc b/gcc/cp/method.cc
> index 98c10e6a8b5..953f1bed6fc 100644
> --- a/gcc/cp/method.cc
> +++ b/gcc/cp/method.cc
> @@ -1928,6 +1928,138 @@ build_trait_object (tree type)
> return build_stub_object (type);
> }
>
> +/* [func.require] Build an expression of INVOKE(FN_TYPE, ARG_TYPES...). If the
> + given is not invocable, returns error_mark_node. */
> +
> +tree
> +build_invoke (tree fn_type, const_tree arg_types, tsubst_flags_t complain)
> +{
> + if (fn_type == error_mark_node || arg_types == error_mark_node)
> + return error_mark_node;
> +
> + gcc_assert (TYPE_P (fn_type));
> + gcc_assert (TREE_CODE (arg_types) == TREE_VEC);
> +
> + /* Access check is required to determine if the given is invocable. */
> + deferring_access_check_sentinel acs (dk_no_deferred);
> +
> + /* INVOKE is an unevaluated context. */
> + cp_unevaluated cp_uneval_guard;
> +
> + bool is_ptrdatamem;
> + bool is_ptrmemfunc;
> + if (TREE_CODE (fn_type) == REFERENCE_TYPE)
> + {
> + tree deref_fn_type = TREE_TYPE (fn_type);
> + is_ptrdatamem = TYPE_PTRDATAMEM_P (deref_fn_type);
> + is_ptrmemfunc = TYPE_PTRMEMFUNC_P (deref_fn_type);
> +
> + /* Dereference fn_type if it is a pointer to member. */
> + if (is_ptrdatamem || is_ptrmemfunc)
> + fn_type = deref_fn_type;
> + }
> + else
> + {
> + is_ptrdatamem = TYPE_PTRDATAMEM_P (fn_type);
> + is_ptrmemfunc = TYPE_PTRMEMFUNC_P (fn_type);
> + }
> +
> + if (is_ptrdatamem && TREE_VEC_LENGTH (arg_types) != 1)
> + /* Only a pointer to data member with one argument is invocable. */
Just one note, if/when build_invoke gets a caller that passes tf_error
(for e.g. elaborating why is_invocable is false, or why invoke_result
is ill-formed) these error_mark_node code paths will need to issue
diagnostics b.
> + return error_mark_node;
> +
> + if (is_ptrmemfunc && TREE_VEC_LENGTH (arg_types) == 0)
> + /* A pointer to member function with no arguments is not invocable. */
> + return error_mark_node;
> +
> + /* Construct an expression of a pointer to member. */
> + tree ptrmem_expr;
> + if (is_ptrdatamem || is_ptrmemfunc)
> + {
> + tree datum_type = TREE_VEC_ELT (arg_types, 0);
> +
> + /* datum must be a class type or a reference/pointer to a class type. */
> + if (TYPE_REF_P (datum_type) || POINTER_TYPE_P (datum_type))
> + {
> + if (!CLASS_TYPE_P (TREE_TYPE (datum_type)))
> + return error_mark_node;
> + }
> + else if (!CLASS_TYPE_P (datum_type))
> + return error_mark_node;
> +
> + bool is_refwrap = false;
> + if (CLASS_TYPE_P (datum_type))
> + {
> + /* 1.2 & 1.5: Handle std::reference_wrapper. */
> + tree datum_decl = TYPE_NAME (TYPE_MAIN_VARIANT (datum_type));
> + if (decl_in_std_namespace_p (datum_decl))
> + {
> + const_tree name = DECL_NAME (datum_decl);
> + if (name && (id_equal (name, "reference_wrapper")))
> + {
> + /* Retrieve T from std::reference_wrapper<T>,
> + i.e., decltype(datum.get()). */
> + datum_type = TREE_VEC_ELT (TYPE_TI_ARGS (datum_type), 0);
> + is_refwrap = true;
> + }
> + }
> + }
> +
> + tree datum_expr = build_trait_object (datum_type);
> + tree fn_expr = build_trait_object (fn_type);
> + ptrmem_expr = build_m_component_ref (datum_expr, fn_expr, complain);
> +
> + if (error_operand_p (ptrmem_expr) && !is_refwrap)
> + {
> + tree ptrmem_class_type = TYPE_PTRMEM_CLASS_TYPE (fn_type);
> + const bool ptrmem_is_base_of_datum =
> + (NON_UNION_CLASS_TYPE_P (ptrmem_class_type)
> + && NON_UNION_CLASS_TYPE_P (datum_type)
> + && (same_type_ignoring_top_level_qualifiers_p (ptrmem_class_type,
> + datum_type)
> + || DERIVED_FROM_P (ptrmem_class_type, datum_type)));
> +
> + if (!ptrmem_is_base_of_datum)
> + {
> + /* 1.3 & 1.6: Try to dereference datum_expr. */
> + datum_expr = build_x_indirect_ref (UNKNOWN_LOCATION, datum_expr,
> + RO_UNARY_STAR, NULL_TREE,
> + complain);
> + /* Rebuild ptrmem_expr. */
> + ptrmem_expr = build_m_component_ref (datum_expr, fn_expr,
> + complain);
> + }
> + }
> + /* 1.1 & 1.4: Otherwise. */
> +
> + if (error_operand_p (ptrmem_expr))
> + return error_mark_node;
> +
> + if (is_ptrdatamem)
> + return ptrmem_expr;
> + }
> +
> + /* Construct expressions for arguments to INVOKE. For a pointer to member
> + function, the first argument, which is the object, is not arguments to
> + the function. */
> + releasing_vec args;
> + for (int i = is_ptrmemfunc ? 1 : 0; i < TREE_VEC_LENGTH (arg_types); ++i)
> + {
> + tree arg_type = TREE_VEC_ELT (arg_types, i);
> + tree arg = build_trait_object (arg_type);
> + vec_safe_push (args, arg);
> + }
> +
> + tree invoke_expr;
> + if (is_ptrmemfunc)
> + invoke_expr = build_offset_ref_call_from_tree (ptrmem_expr, &args,
> + complain);
> + else /* 1.7. */
> + invoke_expr = finish_call_expr (build_trait_object (fn_type), &args, false,
> + false, complain);
> + return invoke_expr;
> +}
> +
> /* Determine which function will be called when looking up NAME in TYPE,
> called with a single ARGTYPE argument, or no argument if ARGTYPE is
> null. FLAGS and COMPLAIN are as for build_new_method_call.
> diff --git a/gcc/cp/semantics.cc b/gcc/cp/semantics.cc
> index 7242db75248..149c0631d62 100644
> --- a/gcc/cp/semantics.cc
> +++ b/gcc/cp/semantics.cc
> @@ -12467,6 +12467,9 @@ trait_expr_value (cp_trait_kind kind, tree type1, tree type2)
> case CPTK_IS_FUNCTION:
> return type_code1 == FUNCTION_TYPE;
>
> + case CPTK_IS_INVOCABLE:
> + return !error_operand_p (build_invoke (type1, type2, tf_none));
> +
> case CPTK_IS_LAYOUT_COMPATIBLE:
> return layout_compatible_type_p (type1, type2);
>
> @@ -12682,6 +12685,7 @@ finish_trait_expr (location_t loc, cp_trait_kind kind, tree type1, tree type2)
> break;
>
> case CPTK_IS_CONVERTIBLE:
> + case CPTK_IS_INVOCABLE:
> case CPTK_IS_NOTHROW_ASSIGNABLE:
> case CPTK_IS_NOTHROW_CONSTRUCTIBLE:
> case CPTK_IS_NOTHROW_CONVERTIBLE:
> diff --git a/gcc/testsuite/g++.dg/ext/has-builtin-1.C b/gcc/testsuite/g++.dg/ext/has-builtin-1.C
> index 7f7b27f7aa7..d2a7ebdf25c 100644
> --- a/gcc/testsuite/g++.dg/ext/has-builtin-1.C
> +++ b/gcc/testsuite/g++.dg/ext/has-builtin-1.C
> @@ -104,6 +104,9 @@
> #if !__has_builtin (__is_function)
> # error "__has_builtin (__is_function) failed"
> #endif
> +#if !__has_builtin (__is_invocable)
> +# error "__has_builtin (__is_invocable) failed"
> +#endif
> #if !__has_builtin (__is_layout_compatible)
> # error "__has_builtin (__is_layout_compatible) failed"
> #endif
> diff --git a/gcc/testsuite/g++.dg/ext/is_invocable1.C b/gcc/testsuite/g++.dg/ext/is_invocable1.C
> new file mode 100644
> index 00000000000..d21ae1d1958
> --- /dev/null
> +++ b/gcc/testsuite/g++.dg/ext/is_invocable1.C
> @@ -0,0 +1,349 @@
> +// { dg-do compile { target c++11 } }
> +
> +#define SA(X) static_assert((X),#X)
> +
> +using func_type_v0 = void(*)();
> +
> +SA( __is_invocable( func_type_v0 ) );
> +SA( ! __is_invocable( func_type_v0, int ) );
> +
> +using func_type_i0 = int(*)();
> +
> +SA( __is_invocable( func_type_i0 ) );
> +SA( ! __is_invocable( func_type_i0, int ) );
> +
> +using func_type_l0 = int&(*)();
> +
> +SA( __is_invocable( func_type_l0 ) );
> +SA( ! __is_invocable( func_type_l0(int) ) );
> +
> +using func_type_ii = int(*)(int);
> +
> +SA( ! __is_invocable( func_type_ii ) );
> +SA( __is_invocable( func_type_ii, int ) );
> +
> +using func_type_il = int(*)(int&);
> +
> +SA( ! __is_invocable( func_type_il ) );
> +SA( ! __is_invocable( func_type_il, int ) );
> +SA( __is_invocable( func_type_il, int& ) );
> +
> +using func_type_ir = int(*)(int&&);
> +
> +SA( ! __is_invocable( func_type_ir ) );
> +SA( ! __is_invocable( func_type_ir, int& ) );
> +SA( __is_invocable( func_type_ir, int ) );
> +SA( __is_invocable( func_type_ir, int&& ) );
> +
> +struct A { };
> +
> +using mem_type_i = int A::*;
> +
> +SA( ! __is_invocable( mem_type_i ) );
> +SA( ! __is_invocable( mem_type_i, int ) );
> +SA( ! __is_invocable( mem_type_i, int* ) );
> +SA( ! __is_invocable( mem_type_i, int& ) );
> +SA( ! __is_invocable( mem_type_i, int&& ) );
> +SA( __is_invocable( mem_type_i, A ) );
> +SA( __is_invocable( mem_type_i, A* ) );
> +SA( __is_invocable( mem_type_i, A& ) );
> +SA( __is_invocable( mem_type_i, A&& ) );
> +SA( __is_invocable( mem_type_i, const A& ) );
> +SA( ! __is_invocable( mem_type_i, A&, int ) );
> +
> +using memfun_type_i = int (A::*)();
> +
> +SA( ! __is_invocable( memfun_type_i ) );
> +SA( ! __is_invocable( memfun_type_i, int ) );
> +SA( ! __is_invocable( memfun_type_i, int* ) );
> +SA( ! __is_invocable( memfun_type_i, int& ) );
> +SA( ! __is_invocable( memfun_type_i, int&& ) );
> +SA( __is_invocable( memfun_type_i, A ) );
> +SA( __is_invocable( memfun_type_i, A* ) );
> +SA( __is_invocable( memfun_type_i, A& ) );
> +SA( __is_invocable( memfun_type_i, A&& ) );
> +SA( ! __is_invocable( memfun_type_i, const A& ) );
> +SA( ! __is_invocable( memfun_type_i, A&, int ) );
> +
> +using memfun_type_ic = int (A::*)() const;
> +
> +SA( ! __is_invocable( memfun_type_ic ) );
> +SA( ! __is_invocable( memfun_type_ic, int ) );
> +SA( ! __is_invocable( memfun_type_ic, int& ) );
> +SA( __is_invocable( memfun_type_ic, A& ) );
> +SA( __is_invocable( memfun_type_ic, A* ) );
> +SA( ! __is_invocable( memfun_type_ic, A&, int ) );
> +SA( ! __is_invocable( memfun_type_ic, A*, int& ) );
> +SA( __is_invocable( memfun_type_ic, const A& ) );
> +SA( __is_invocable( memfun_type_ic, const A* ) );
> +SA( ! __is_invocable( memfun_type_ic, const A&, int& ) );
> +SA( ! __is_invocable( memfun_type_ic, const A*, int ) );
> +
> +using memfun_type_iic = int& (A::*)(int&) const;
> +
> +SA( ! __is_invocable( memfun_type_iic ) );
> +SA( ! __is_invocable( memfun_type_iic, int ) );
> +SA( ! __is_invocable( memfun_type_iic, int& ) );
> +SA( ! __is_invocable( memfun_type_iic, A&, int ) );
> +SA( __is_invocable( memfun_type_iic, A&, int& ) );
> +SA( ! __is_invocable( memfun_type_iic, A*, int ) );
> +SA( __is_invocable( memfun_type_iic, A*, int& ) );
> +SA( ! __is_invocable( memfun_type_iic, const A&, int ) );
> +SA( ! __is_invocable( memfun_type_iic, const A&, int&, int ) );
> +SA( __is_invocable( memfun_type_iic, const A&, int& ) );
> +SA( __is_invocable( memfun_type_iic, const A*, int& ) );
> +
> +struct B {
> + int& operator()();
> + long& operator()() const;
> + bool& operator()(int);
> +private:
> + void operator()(int, int);
> +};
> +using CB = const B;
> +
> +SA( __is_invocable( B ) );
> +SA( __is_invocable( B& ) );
> +SA( __is_invocable( B&& ) );
> +SA( ! __is_invocable( B* ) );
> +SA( __is_invocable( CB ) );
> +SA( __is_invocable( CB& ) );
> +SA( ! __is_invocable( CB* ) );
> +
> +SA( __is_invocable( B, int ) );
> +SA( __is_invocable( B&, int ) );
> +SA( __is_invocable( B&&, int ) );
> +SA( ! __is_invocable( B*, int ) );
> +SA( ! __is_invocable( CB, int ) );
> +SA( ! __is_invocable( CB&, int ) );
> +SA( ! __is_invocable( CB*, int ) );
> +
> +SA( ! __is_invocable( B, int, int ) );
> +SA( ! __is_invocable( B&, int, int ) );
> +SA( ! __is_invocable( B&&, int, int ) );
> +SA( ! __is_invocable( B*, int, int ) );
> +SA( ! __is_invocable( CB, int, int ) );
> +SA( ! __is_invocable( CB&, int, int ) );
> +SA( ! __is_invocable( CB*, int, int ) );
> +
> +struct C : B { int& operator()() = delete; };
> +using CC = const C;
> +
> +SA( ! __is_invocable( C ) );
> +SA( ! __is_invocable( C& ) );
> +SA( ! __is_invocable( C&& ) );
> +SA( ! __is_invocable( C* ) );
> +SA( ! __is_invocable( CC ) );
> +SA( ! __is_invocable( CC& ) );
> +SA( ! __is_invocable( CC* ) );
> +
> +struct D { B operator*(); };
> +using CD = const D;
> +
> +SA( ! __is_invocable( D ) );
> +
> +struct E { void v(); };
> +using CE = const E;
> +
> +SA( ! __is_invocable( E ) );
> +SA( ! __is_invocable( void (E::*)() ) );
> +SA( __is_invocable( void (E::*)(), E ) );
> +SA( __is_invocable( void (E::*)(), E* ) );
> +SA( ! __is_invocable( void (E::*)(), CE ) );
> +
> +struct F : E {};
> +using CF = const F;
> +
> +SA( ! __is_invocable( F ) );
> +SA( __is_invocable( void (E::*)(), F ) );
> +SA( __is_invocable( void (E::*)(), F* ) );
> +SA( ! __is_invocable( void (E::*)(), CF ) );
> +
> +struct G { E operator*(); };
> +using CG = const G;
> +
> +SA( ! __is_invocable( G ) );
> +SA( __is_invocable( void (E::*)(), G ) );
> +SA( ! __is_invocable( void (E::*)(), G* ) );
> +SA( ! __is_invocable( void (E::*)(), CG ) );
> +
> +struct H { E& operator*(); };
> +using CH = const H;
> +
> +SA( ! __is_invocable( H ) );
> +SA( __is_invocable( void (E::*)(), H ) );
> +SA( ! __is_invocable( void (E::*)(), H* ) );
> +SA( ! __is_invocable( void (E::*)(), CH ) );
> +
> +struct I { E&& operator*(); };
> +using CI = const I;
> +
> +SA( ! __is_invocable( I ) );
> +SA( __is_invocable( void (E::*)(), I ) );
> +SA( ! __is_invocable( void (E::*)(), I* ) );
> +SA( ! __is_invocable( void (E::*)(), CI ) );
> +
> +struct K { E* operator*(); };
> +using CK = const K;
> +
> +SA( ! __is_invocable( K ) );
> +SA( ! __is_invocable( void (E::*)(), K ) );
> +SA( ! __is_invocable( void (E::*)(), K* ) );
> +SA( ! __is_invocable( void (E::*)(), CK ) );
> +
> +struct L { CE operator*(); };
> +using CL = const L;
> +
> +SA( ! __is_invocable( L ) );
> +SA( ! __is_invocable( void (E::*)(), L ) );
> +SA( ! __is_invocable( void (E::*)(), L* ) );
> +SA( ! __is_invocable( void (E::*)(), CL ) );
> +
> +struct M {
> + int i;
> +private:
> + long l;
> +};
> +using CM = const M;
> +
> +SA( ! __is_invocable( M ) );
> +SA( ! __is_invocable( M& ) );
> +SA( ! __is_invocable( M&& ) );
> +SA( ! __is_invocable( M* ) );
> +SA( ! __is_invocable( CM ) );
> +SA( ! __is_invocable( CM& ) );
> +SA( ! __is_invocable( CM* ) );
> +
> +SA( ! __is_invocable( int M::* ) );
> +SA( __is_invocable( int M::*, M ) );
> +SA( __is_invocable( int M::*, M& ) );
> +SA( __is_invocable( int M::*, M&& ) );
> +SA( __is_invocable( int M::*, M* ) );
> +SA( __is_invocable( int M::*, CM ) );
> +SA( __is_invocable( int M::*, CM& ) );
> +SA( __is_invocable( int M::*, CM* ) );
> +SA( ! __is_invocable( int M::*, int ) );
> +
> +SA( ! __is_invocable( int CM::* ) );
> +SA( __is_invocable( int CM::*, M ) );
> +SA( __is_invocable( int CM::*, M& ) );
> +SA( __is_invocable( int CM::*, M&& ) );
> +SA( __is_invocable( int CM::*, M* ) );
> +SA( __is_invocable( int CM::*, CM ) );
> +SA( __is_invocable( int CM::*, CM& ) );
> +SA( __is_invocable( int CM::*, CM* ) );
> +SA( ! __is_invocable( int CM::*, int ) );
> +
> +SA( ! __is_invocable( long M::* ) );
> +SA( __is_invocable( long M::*, M ) );
> +SA( __is_invocable( long M::*, M& ) );
> +SA( __is_invocable( long M::*, M&& ) );
> +SA( __is_invocable( long M::*, M* ) );
> +SA( __is_invocable( long M::*, CM ) );
> +SA( __is_invocable( long M::*, CM& ) );
> +SA( __is_invocable( long M::*, CM* ) );
> +SA( ! __is_invocable( long M::*, long ) );
> +
> +SA( ! __is_invocable( long CM::* ) );
> +SA( __is_invocable( long CM::*, M ) );
> +SA( __is_invocable( long CM::*, M& ) );
> +SA( __is_invocable( long CM::*, M&& ) );
> +SA( __is_invocable( long CM::*, M* ) );
> +SA( __is_invocable( long CM::*, CM ) );
> +SA( __is_invocable( long CM::*, CM& ) );
> +SA( __is_invocable( long CM::*, CM* ) );
> +SA( ! __is_invocable( long CM::*, long ) );
> +
> +SA( ! __is_invocable( short M::* ) );
> +SA( __is_invocable( short M::*, M ) );
> +SA( __is_invocable( short M::*, M& ) );
> +SA( __is_invocable( short M::*, M&& ) );
> +SA( __is_invocable( short M::*, M* ) );
> +SA( __is_invocable( short M::*, CM ) );
> +SA( __is_invocable( short M::*, CM& ) );
> +SA( __is_invocable( short M::*, CM* ) );
> +SA( ! __is_invocable( short M::*, short ) );
> +
> +SA( ! __is_invocable( short CM::* ) );
> +SA( __is_invocable( short CM::*, M ) );
> +SA( __is_invocable( short CM::*, M& ) );
> +SA( __is_invocable( short CM::*, M&& ) );
> +SA( __is_invocable( short CM::*, M* ) );
> +SA( __is_invocable( short CM::*, CM ) );
> +SA( __is_invocable( short CM::*, CM& ) );
> +SA( __is_invocable( short CM::*, CM* ) );
> +SA( ! __is_invocable( short CM::*, short ) );
> +
> +struct N { M operator*(); };
> +SA( __is_invocable( int M::*, N ) );
> +SA( ! __is_invocable( int M::*, N* ) );
> +
> +struct O { M& operator*(); };
> +SA( __is_invocable( int M::*, O ) );
> +SA( ! __is_invocable( int M::*, O* ) );
> +
> +struct P { M&& operator*(); };
> +SA( __is_invocable( int M::*, P ) );
> +SA( ! __is_invocable( int M::*, P* ) );
> +
> +struct Q { M* operator*(); };
> +SA( ! __is_invocable( int M::*, Q ) );
> +SA( ! __is_invocable( int M::*, Q* ) );
> +
> +struct R { void operator()(int = 0); };
> +
> +SA( __is_invocable( R ) );
> +SA( __is_invocable( R, int ) );
> +SA( ! __is_invocable( R, int, int ) );
> +
> +struct S { void operator()(int, ...); };
> +
> +SA( ! __is_invocable( S ) );
> +SA( __is_invocable( S, int ) );
> +SA( __is_invocable( S, int, int ) );
> +SA( __is_invocable( S, int, int, int ) );
> +
> +void fn1() {}
> +
> +SA( __is_invocable( decltype(fn1) ) );
> +
> +void fn2(int arr[10]);
> +
> +SA( __is_invocable( decltype(fn2), int[10] ) );
> +SA( __is_invocable( decltype(fn2), int(&)[10] ) );
> +SA( __is_invocable( decltype(fn2), int(&&)[10] ) );
> +SA( ! __is_invocable( decltype(fn2), int(*)[10] ) );
> +SA( ! __is_invocable( decltype(fn2), int(*&)[10] ) );
> +SA( ! __is_invocable( decltype(fn2), int(*&&)[10] ) );
> +SA( __is_invocable( decltype(fn2), int[] ) );
> +
> +auto lambda = []() {};
> +
> +SA( __is_invocable( decltype(lambda) ) );
> +
> +template <typename Func, typename... Args>
> +struct can_invoke {
> + static constexpr bool value = __is_invocable( Func, Args... );
> +};
> +
> +SA( can_invoke<decltype(lambda)>::value );
> +
> +struct T {
> + void func() const {}
> + int data;
> +};
> +
> +SA( __is_invocable( decltype(&T::func)&, T& ) );
> +SA( __is_invocable( decltype(&T::data)&, T& ) );
> +
> +struct U { };
> +struct V : U { U& operator*() = delete; };
> +SA( __is_invocable( int U::*, V ) );
> +
> +struct W : private U { U& operator*(); };
> +SA( ! __is_invocable( int U::*, W ) );
> +
> +struct X { int m; };
> +struct Y { X& operator*(); };
> +struct Z : Y { };
> +SA( __is_invocable(int X::*, Z) );
> diff --git a/gcc/testsuite/g++.dg/ext/is_invocable2.C b/gcc/testsuite/g++.dg/ext/is_invocable2.C
> new file mode 100644
> index 00000000000..a68aefd3e13
> --- /dev/null
> +++ b/gcc/testsuite/g++.dg/ext/is_invocable2.C
> @@ -0,0 +1,139 @@
> +// { dg-do compile { target c++11 } }
> +// __is_invocable should handle std::reference_wrapper correctly.
> +
> +#include <functional>
> +
> +#define SA(X) static_assert((X),#X)
> +
> +using std::reference_wrapper;
> +
> +using func_type_v0 = void(*)();
> +
> +SA( __is_invocable( reference_wrapper<func_type_v0> ) );
> +SA( ! __is_invocable( reference_wrapper<func_type_v0>, int ) );
> +
> +using func_type_i0 = int(*)();
> +
> +SA( __is_invocable( reference_wrapper<func_type_i0> ) );
> +SA( ! __is_invocable( reference_wrapper<func_type_i0>, int ) );
> +
> +using func_type_l0 = int&(*)();
> +
> +SA( __is_invocable( reference_wrapper<func_type_l0> ) );
> +SA( ! __is_invocable( reference_wrapper<func_type_l0(int)> ) );
> +
> +using func_type_ii = int(*)(int);
> +
> +SA( ! __is_invocable( reference_wrapper<func_type_ii> ) );
> +SA( __is_invocable( reference_wrapper<func_type_ii>, int ) );
> +
> +using func_type_il = int(*)(int&);
> +
> +SA( ! __is_invocable( reference_wrapper<func_type_il> ) );
> +SA( ! __is_invocable( reference_wrapper<func_type_il>, int ) );
> +SA( __is_invocable( reference_wrapper<func_type_il>, int& ) );
> +
> +using func_type_ir = int(*)(int&&);
> +
> +SA( ! __is_invocable( reference_wrapper<func_type_ir> ) );
> +SA( ! __is_invocable( reference_wrapper<func_type_ir>, int& ) );
> +SA( __is_invocable( reference_wrapper<func_type_ir>, int ) );
> +SA( __is_invocable( reference_wrapper<func_type_ir>, int&& ) );
> +
> +struct A { };
> +
> +using mem_type_i = int A::*;
> +
> +SA( ! __is_invocable( reference_wrapper<mem_type_i> ) );
> +SA( ! __is_invocable( reference_wrapper<mem_type_i>, int ) );
> +SA( ! __is_invocable( reference_wrapper<mem_type_i>, int* ) );
> +SA( ! __is_invocable( reference_wrapper<mem_type_i>, int& ) );
> +SA( ! __is_invocable( reference_wrapper<mem_type_i>, int&& ) );
> +SA( __is_invocable( reference_wrapper<mem_type_i>, A ) );
> +SA( __is_invocable( reference_wrapper<mem_type_i>, A* ) );
> +SA( __is_invocable( reference_wrapper<mem_type_i>, A& ) );
> +SA( __is_invocable( reference_wrapper<mem_type_i>, A&& ) );
> +
> +using memfun_type_i = int (A::*)();
> +
> +SA( ! __is_invocable( reference_wrapper<memfun_type_i> ) );
> +SA( ! __is_invocable( reference_wrapper<memfun_type_i>, int ) );
> +SA( ! __is_invocable( reference_wrapper<memfun_type_i>, int* ) );
> +SA( ! __is_invocable( reference_wrapper<memfun_type_i>, int& ) );
> +SA( ! __is_invocable( reference_wrapper<memfun_type_i>, int&& ) );
> +SA( __is_invocable( reference_wrapper<memfun_type_i>, A ) );
> +SA( __is_invocable( reference_wrapper<memfun_type_i>, A* ) );
> +SA( __is_invocable( reference_wrapper<memfun_type_i>, A& ) );
> +SA( __is_invocable( reference_wrapper<memfun_type_i>, A&& ) );
> +SA( ! __is_invocable( reference_wrapper<memfun_type_i>, const A& ) );
> +SA( ! __is_invocable( reference_wrapper<memfun_type_i>, A&, int ) );
> +
> +using memfun_type_ic = int (A::*)() const;
> +
> +SA( ! __is_invocable( reference_wrapper<memfun_type_ic> ) );
> +SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, int ) );
> +SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, int& ) );
> +SA( __is_invocable( reference_wrapper<memfun_type_ic>, A& ) );
> +SA( __is_invocable( reference_wrapper<memfun_type_ic>, A* ) );
> +SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, A&, int ) );
> +SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, A*, int& ) );
> +SA( __is_invocable( reference_wrapper<memfun_type_ic>, const A& ) );
> +SA( __is_invocable( reference_wrapper<memfun_type_ic>, const A* ) );
> +SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, const A&, int& ) );
> +SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, const A*, int ) );
> +
> +using memfun_type_iic = int& (A::*)(int&) const;
> +
> +SA( ! __is_invocable( reference_wrapper<memfun_type_iic> ) );
> +SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, int ) );
> +SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, int& ) );
> +SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, A&, int ) );
> +SA( __is_invocable( reference_wrapper<memfun_type_iic>, A&, int& ) );
> +SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, A*, int ) );
> +SA( __is_invocable( reference_wrapper<memfun_type_iic>, A*, int& ) );
> +SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, const A&, int ) );
> +SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, const A&, int&, int ) );
> +SA( __is_invocable( reference_wrapper<memfun_type_iic>, const A&, int& ) );
> +SA( __is_invocable( reference_wrapper<memfun_type_iic>, const A*, int& ) );
> +
> +struct B {
> + int& operator()();
> + long& operator()() const;
> + bool& operator()(int);
> +private:
> + void operator()(int, int);
> +};
> +using CB = const B;
> +
> +SA( __is_invocable( reference_wrapper<B> ) );
> +SA( __is_invocable( reference_wrapper<B>& ) );
> +SA( __is_invocable( reference_wrapper<B>&& ) );
> +SA( __is_invocable( reference_wrapper<CB> ) );
> +SA( __is_invocable( reference_wrapper<CB>& ) );
> +SA( __is_invocable( reference_wrapper<B>, int ) );
> +SA( ! __is_invocable( reference_wrapper<B>&, int, int ) );
> +
> +struct C : B { int& operator()() = delete; };
> +using CC = const C;
> +
> +SA( ! __is_invocable( reference_wrapper<C> ) );
> +SA( ! __is_invocable( reference_wrapper<C>& ) );
> +SA( ! __is_invocable( reference_wrapper<C>&& ) );
> +SA( ! __is_invocable( reference_wrapper<CC> ) );
> +SA( ! __is_invocable( reference_wrapper<CC>& ) );
> +
> +struct D { B operator*(); };
> +using CD = const D;
> +
> +SA( ! __is_invocable( reference_wrapper<D> ) );
> +SA( ! __is_invocable( reference_wrapper<D>& ) );
> +SA( ! __is_invocable( reference_wrapper<D>&& ) );
> +SA( ! __is_invocable( reference_wrapper<D>* ) );
> +SA( ! __is_invocable( reference_wrapper<D*> ) );
> +SA( ! __is_invocable( reference_wrapper<D*>* ) );
> +
> +std::function<void()> fn = []() {};
> +auto refwrap = std::ref(fn);
> +
> +SA( __is_invocable( decltype(fn) ) );
> +SA( __is_invocable( decltype(refwrap) ) );
> diff --git a/gcc/testsuite/g++.dg/ext/is_invocable3.C b/gcc/testsuite/g++.dg/ext/is_invocable3.C
> new file mode 100644
> index 00000000000..8699b0a53ca
> --- /dev/null
> +++ b/gcc/testsuite/g++.dg/ext/is_invocable3.C
> @@ -0,0 +1,51 @@
> +// { dg-do compile { target c++11 } }
> +// __is_invocable should handle incomplete class correctly.
> +
> +#define SA(X) static_assert((X),#X)
> +
> +struct Incomplete;
> +
> +SA( ! __is_invocable( Incomplete ) ); // { dg-error "incomplete type" }
> +SA( ! __is_invocable( Incomplete, int ) ); // { dg-error "incomplete type" }
> +
> +SA( ! __is_invocable( int, Incomplete, int ) ); // { dg-error "incomplete type" }
> +SA( ! __is_invocable( int, Incomplete ) ); // { dg-error "incomplete type" }
> +
> +SA( ! __is_invocable( Incomplete, Incomplete() ) ); // { dg-error "incomplete type" }
> +SA( ! __is_invocable( Incomplete, Incomplete(int), int ) ); // { dg-error "incomplete type" }
> +SA( ! __is_invocable( Incomplete, Incomplete(int, int), int, int ) ); // { dg-error "incomplete type" }
> +
> +SA( ! __is_invocable( Incomplete, Incomplete(), int, int ) ); // { dg-error "incomplete type" }
> +
> +SA( ! __is_invocable( int(Incomplete), Incomplete ) ); // { dg-error "incomplete type" }
> +SA( ! __is_invocable( int(int, Incomplete), int, Incomplete ) ); // { dg-error "incomplete type" }
> +SA( ! __is_invocable( int(int, Incomplete), Incomplete, int ) ); // { dg-error "incomplete type" }
> +
> +SA( __is_invocable( int(Incomplete&), Incomplete& ) ); // { dg-bogus "incomplete type" }
> +SA( __is_invocable( int(int, Incomplete&), int, Incomplete& ) ); // { dg-bogus "incomplete type" }
> +
> +SA( __is_invocable( int(Incomplete&&), Incomplete&& ) ); // { dg-bogus "incomplete type" }
> +SA( __is_invocable( int(int, Incomplete&&), int, Incomplete&& ) ); // { dg-bogus "incomplete type" }
> +
> +SA( __is_invocable( int(const Incomplete&&), const Incomplete&& ) ); // { dg-bogus "incomplete type" }
> +SA( __is_invocable( int(int, const Incomplete&&), int, const Incomplete&& ) ); // { dg-bogus "incomplete type" }
> +
> +SA( __is_invocable( int(const Incomplete&), const Incomplete& ) ); // { dg-bogus "incomplete type" }
> +SA( __is_invocable( int(int, const Incomplete&), int, const Incomplete& ) ); // { dg-bogus "incomplete type" }
> +
> +SA( __is_invocable( int(const Incomplete&), Incomplete& ) ); // { dg-bogus "incomplete type" }
> +SA( __is_invocable( int(int, const Incomplete&), int, Incomplete& ) ); // { dg-bogus "incomplete type" }
> +
> +SA( __is_invocable( int Incomplete::*, const Incomplete& ) ); // { dg-bogus "incomplete type" }
> +SA( ! __is_invocable( void (Incomplete::*)(long&), const Incomplete*, long& ) ); // { dg-bogus "incomplete type" }
> +SA( __is_invocable( void (Incomplete::*)(long&) const, Incomplete*, long& ) ); // { dg-bogus "incomplete type" }
> +
> +template <typename T>
> +struct Holder { T t; };
> +
> +SA( __is_invocable( int(Holder<Incomplete>&), Holder<Incomplete>& ) ); // { dg-bogus "incomplete type" }
> +
> +// Define Incomplete, which is now not incomplete.
> +struct Incomplete { void operator()(); };
> +
> +SA( __is_invocable( Incomplete ) ); // { dg-bogus "incomplete type" }
> diff --git a/gcc/testsuite/g++.dg/ext/is_invocable4.C b/gcc/testsuite/g++.dg/ext/is_invocable4.C
> new file mode 100644
> index 00000000000..d1efccf08f8
> --- /dev/null
> +++ b/gcc/testsuite/g++.dg/ext/is_invocable4.C
> @@ -0,0 +1,33 @@
> +// { dg-do compile { target c++11 } }
> +// Failed access check should be a substitution failure, not an error.
> +
> +#define SA(X) static_assert((X),#X)
> +
> +template<bool B>
> +struct bool_constant { static constexpr bool value = B; };
> +
> +template<typename _Fn, typename... _ArgTypes>
> +struct is_invocable
> +: public bool_constant<__is_invocable(_Fn, _ArgTypes...)>
> +{ };
> +
> +#if __cpp_variable_templates
> +template<typename _Fn, typename... _ArgTypes>
> +constexpr bool is_invocable_v = __is_invocable(_Fn, _ArgTypes...);
> +#endif
> +
> +class Private
> +{
> + void operator()() const
> + {
> + SA( ! is_invocable<Private>::value );
> +#if __cpp_variable_templates
> + SA( ! is_invocable_v<Private> );
> +#endif
> + }
> +};
> +
> +SA( ! is_invocable<Private>::value );
> +#if __cpp_variable_templates
> +SA( ! is_invocable_v<Private> );
> +#endif
> --
> 2.44.0
>
>
On Fri, Mar 8, 2024 at 9:17 AM Patrick Palka <ppalka@redhat.com> wrote:
>
> On Wed, 28 Feb 2024, Ken Matsui wrote:
>
> > This patch implements built-in trait for std::is_invocable.
> >
> > gcc/cp/ChangeLog:
> >
> > * cp-trait.def: Define __is_invocable.
> > * constraint.cc (diagnose_trait_expr): Handle CPTK_IS_INVOCABLE.
> > * semantics.cc (trait_expr_value): Likewise.
> > (finish_trait_expr): Likewise.
> > * cp-tree.h (build_invoke): New function.
> > * method.cc (build_invoke): New function.
> >
> > gcc/testsuite/ChangeLog:
> >
> > * g++.dg/ext/has-builtin-1.C: Test existence of __is_invocable.
> > * g++.dg/ext/is_invocable1.C: New test.
> > * g++.dg/ext/is_invocable2.C: New test.
> > * g++.dg/ext/is_invocable3.C: New test.
> > * g++.dg/ext/is_invocable4.C: New test.
>
> Thanks, this looks great! This generic build_invoke function could be
> used for invoke_result etc as well, and it could also cache the built-up
> call across __is_invocable and __is_nothrow_invocable checks on the same
> arguments (which is a common pattern in the standard library). LGTM
Thank you!!! Yes, I will also work on those features!
>
> >
> > Signed-off-by: Ken Matsui <kmatsui@gcc.gnu.org>
> > ---
> > gcc/cp/constraint.cc | 6 +
> > gcc/cp/cp-trait.def | 1 +
> > gcc/cp/cp-tree.h | 2 +
> > gcc/cp/method.cc | 132 +++++++++
> > gcc/cp/semantics.cc | 4 +
> > gcc/testsuite/g++.dg/ext/has-builtin-1.C | 3 +
> > gcc/testsuite/g++.dg/ext/is_invocable1.C | 349 +++++++++++++++++++++++
> > gcc/testsuite/g++.dg/ext/is_invocable2.C | 139 +++++++++
> > gcc/testsuite/g++.dg/ext/is_invocable3.C | 51 ++++
> > gcc/testsuite/g++.dg/ext/is_invocable4.C | 33 +++
> > 10 files changed, 720 insertions(+)
> > create mode 100644 gcc/testsuite/g++.dg/ext/is_invocable1.C
> > create mode 100644 gcc/testsuite/g++.dg/ext/is_invocable2.C
> > create mode 100644 gcc/testsuite/g++.dg/ext/is_invocable3.C
> > create mode 100644 gcc/testsuite/g++.dg/ext/is_invocable4.C
> >
> > diff --git a/gcc/cp/constraint.cc b/gcc/cp/constraint.cc
> > index 23ea66d9c12..c87b126fdb1 100644
> > --- a/gcc/cp/constraint.cc
> > +++ b/gcc/cp/constraint.cc
> > @@ -3791,6 +3791,12 @@ diagnose_trait_expr (tree expr, tree args)
> > case CPTK_IS_FUNCTION:
> > inform (loc, " %qT is not a function", t1);
> > break;
> > + case CPTK_IS_INVOCABLE:
> > + if (!t2)
> > + inform (loc, " %qT is not invocable", t1);
> > + else
> > + inform (loc, " %qT is not invocable by %qE", t1, t2);
> > + break;
> > case CPTK_IS_LAYOUT_COMPATIBLE:
> > inform (loc, " %qT is not layout compatible with %qT", t1, t2);
> > break;
> > diff --git a/gcc/cp/cp-trait.def b/gcc/cp/cp-trait.def
> > index 85056c8140b..6cb2b55f4ea 100644
> > --- a/gcc/cp/cp-trait.def
> > +++ b/gcc/cp/cp-trait.def
> > @@ -75,6 +75,7 @@ DEFTRAIT_EXPR (IS_EMPTY, "__is_empty", 1)
> > DEFTRAIT_EXPR (IS_ENUM, "__is_enum", 1)
> > DEFTRAIT_EXPR (IS_FINAL, "__is_final", 1)
> > DEFTRAIT_EXPR (IS_FUNCTION, "__is_function", 1)
> > +DEFTRAIT_EXPR (IS_INVOCABLE, "__is_invocable", -1)
> > DEFTRAIT_EXPR (IS_LAYOUT_COMPATIBLE, "__is_layout_compatible", 2)
> > DEFTRAIT_EXPR (IS_LITERAL_TYPE, "__is_literal_type", 1)
> > DEFTRAIT_EXPR (IS_MEMBER_FUNCTION_POINTER, "__is_member_function_pointer", 1)
> > diff --git a/gcc/cp/cp-tree.h b/gcc/cp/cp-tree.h
> > index 334c11396c2..261d3a71faa 100644
> > --- a/gcc/cp/cp-tree.h
> > +++ b/gcc/cp/cp-tree.h
> > @@ -7334,6 +7334,8 @@ extern tree get_copy_assign (tree);
> > extern tree get_default_ctor (tree);
> > extern tree get_dtor (tree, tsubst_flags_t);
> > extern tree build_stub_object (tree);
> > +extern tree build_invoke (tree, const_tree,
> > + tsubst_flags_t);
> > extern tree strip_inheriting_ctors (tree);
> > extern tree inherited_ctor_binfo (tree);
> > extern bool base_ctor_omit_inherited_parms (tree);
> > diff --git a/gcc/cp/method.cc b/gcc/cp/method.cc
> > index 98c10e6a8b5..953f1bed6fc 100644
> > --- a/gcc/cp/method.cc
> > +++ b/gcc/cp/method.cc
> > @@ -1928,6 +1928,138 @@ build_trait_object (tree type)
> > return build_stub_object (type);
> > }
> >
> > +/* [func.require] Build an expression of INVOKE(FN_TYPE, ARG_TYPES...). If the
> > + given is not invocable, returns error_mark_node. */
> > +
> > +tree
> > +build_invoke (tree fn_type, const_tree arg_types, tsubst_flags_t complain)
> > +{
> > + if (fn_type == error_mark_node || arg_types == error_mark_node)
> > + return error_mark_node;
> > +
> > + gcc_assert (TYPE_P (fn_type));
> > + gcc_assert (TREE_CODE (arg_types) == TREE_VEC);
> > +
> > + /* Access check is required to determine if the given is invocable. */
> > + deferring_access_check_sentinel acs (dk_no_deferred);
> > +
> > + /* INVOKE is an unevaluated context. */
> > + cp_unevaluated cp_uneval_guard;
> > +
> > + bool is_ptrdatamem;
> > + bool is_ptrmemfunc;
> > + if (TREE_CODE (fn_type) == REFERENCE_TYPE)
> > + {
> > + tree deref_fn_type = TREE_TYPE (fn_type);
> > + is_ptrdatamem = TYPE_PTRDATAMEM_P (deref_fn_type);
> > + is_ptrmemfunc = TYPE_PTRMEMFUNC_P (deref_fn_type);
> > +
> > + /* Dereference fn_type if it is a pointer to member. */
> > + if (is_ptrdatamem || is_ptrmemfunc)
> > + fn_type = deref_fn_type;
> > + }
> > + else
> > + {
> > + is_ptrdatamem = TYPE_PTRDATAMEM_P (fn_type);
> > + is_ptrmemfunc = TYPE_PTRMEMFUNC_P (fn_type);
> > + }
> > +
> > + if (is_ptrdatamem && TREE_VEC_LENGTH (arg_types) != 1)
> > + /* Only a pointer to data member with one argument is invocable. */
>
> Just one note, if/when build_invoke gets a caller that passes tf_error
> (for e.g. elaborating why is_invocable is false, or why invoke_result
> is ill-formed) these error_mark_node code paths will need to issue
> diagnostics b.
Oh I see. I will update this patch. Thank you!
>
> > + return error_mark_node;
> > +
> > + if (is_ptrmemfunc && TREE_VEC_LENGTH (arg_types) == 0)
> > + /* A pointer to member function with no arguments is not invocable. */
> > + return error_mark_node;
> > +
> > + /* Construct an expression of a pointer to member. */
> > + tree ptrmem_expr;
> > + if (is_ptrdatamem || is_ptrmemfunc)
> > + {
> > + tree datum_type = TREE_VEC_ELT (arg_types, 0);
> > +
> > + /* datum must be a class type or a reference/pointer to a class type. */
> > + if (TYPE_REF_P (datum_type) || POINTER_TYPE_P (datum_type))
> > + {
> > + if (!CLASS_TYPE_P (TREE_TYPE (datum_type)))
> > + return error_mark_node;
> > + }
> > + else if (!CLASS_TYPE_P (datum_type))
> > + return error_mark_node;
> > +
> > + bool is_refwrap = false;
> > + if (CLASS_TYPE_P (datum_type))
> > + {
> > + /* 1.2 & 1.5: Handle std::reference_wrapper. */
> > + tree datum_decl = TYPE_NAME (TYPE_MAIN_VARIANT (datum_type));
> > + if (decl_in_std_namespace_p (datum_decl))
> > + {
> > + const_tree name = DECL_NAME (datum_decl);
> > + if (name && (id_equal (name, "reference_wrapper")))
> > + {
> > + /* Retrieve T from std::reference_wrapper<T>,
> > + i.e., decltype(datum.get()). */
> > + datum_type = TREE_VEC_ELT (TYPE_TI_ARGS (datum_type), 0);
> > + is_refwrap = true;
> > + }
> > + }
> > + }
> > +
> > + tree datum_expr = build_trait_object (datum_type);
> > + tree fn_expr = build_trait_object (fn_type);
> > + ptrmem_expr = build_m_component_ref (datum_expr, fn_expr, complain);
> > +
> > + if (error_operand_p (ptrmem_expr) && !is_refwrap)
> > + {
> > + tree ptrmem_class_type = TYPE_PTRMEM_CLASS_TYPE (fn_type);
> > + const bool ptrmem_is_base_of_datum =
> > + (NON_UNION_CLASS_TYPE_P (ptrmem_class_type)
> > + && NON_UNION_CLASS_TYPE_P (datum_type)
> > + && (same_type_ignoring_top_level_qualifiers_p (ptrmem_class_type,
> > + datum_type)
> > + || DERIVED_FROM_P (ptrmem_class_type, datum_type)));
> > +
> > + if (!ptrmem_is_base_of_datum)
> > + {
> > + /* 1.3 & 1.6: Try to dereference datum_expr. */
> > + datum_expr = build_x_indirect_ref (UNKNOWN_LOCATION, datum_expr,
> > + RO_UNARY_STAR, NULL_TREE,
> > + complain);
> > + /* Rebuild ptrmem_expr. */
> > + ptrmem_expr = build_m_component_ref (datum_expr, fn_expr,
> > + complain);
> > + }
> > + }
> > + /* 1.1 & 1.4: Otherwise. */
> > +
> > + if (error_operand_p (ptrmem_expr))
> > + return error_mark_node;
> > +
> > + if (is_ptrdatamem)
> > + return ptrmem_expr;
> > + }
> > +
> > + /* Construct expressions for arguments to INVOKE. For a pointer to member
> > + function, the first argument, which is the object, is not arguments to
> > + the function. */
> > + releasing_vec args;
> > + for (int i = is_ptrmemfunc ? 1 : 0; i < TREE_VEC_LENGTH (arg_types); ++i)
> > + {
> > + tree arg_type = TREE_VEC_ELT (arg_types, i);
> > + tree arg = build_trait_object (arg_type);
> > + vec_safe_push (args, arg);
> > + }
> > +
> > + tree invoke_expr;
> > + if (is_ptrmemfunc)
> > + invoke_expr = build_offset_ref_call_from_tree (ptrmem_expr, &args,
> > + complain);
> > + else /* 1.7. */
> > + invoke_expr = finish_call_expr (build_trait_object (fn_type), &args, false,
> > + false, complain);
> > + return invoke_expr;
> > +}
> > +
> > /* Determine which function will be called when looking up NAME in TYPE,
> > called with a single ARGTYPE argument, or no argument if ARGTYPE is
> > null. FLAGS and COMPLAIN are as for build_new_method_call.
> > diff --git a/gcc/cp/semantics.cc b/gcc/cp/semantics.cc
> > index 7242db75248..149c0631d62 100644
> > --- a/gcc/cp/semantics.cc
> > +++ b/gcc/cp/semantics.cc
> > @@ -12467,6 +12467,9 @@ trait_expr_value (cp_trait_kind kind, tree type1, tree type2)
> > case CPTK_IS_FUNCTION:
> > return type_code1 == FUNCTION_TYPE;
> >
> > + case CPTK_IS_INVOCABLE:
> > + return !error_operand_p (build_invoke (type1, type2, tf_none));
> > +
> > case CPTK_IS_LAYOUT_COMPATIBLE:
> > return layout_compatible_type_p (type1, type2);
> >
> > @@ -12682,6 +12685,7 @@ finish_trait_expr (location_t loc, cp_trait_kind kind, tree type1, tree type2)
> > break;
> >
> > case CPTK_IS_CONVERTIBLE:
> > + case CPTK_IS_INVOCABLE:
> > case CPTK_IS_NOTHROW_ASSIGNABLE:
> > case CPTK_IS_NOTHROW_CONSTRUCTIBLE:
> > case CPTK_IS_NOTHROW_CONVERTIBLE:
> > diff --git a/gcc/testsuite/g++.dg/ext/has-builtin-1.C b/gcc/testsuite/g++.dg/ext/has-builtin-1.C
> > index 7f7b27f7aa7..d2a7ebdf25c 100644
> > --- a/gcc/testsuite/g++.dg/ext/has-builtin-1.C
> > +++ b/gcc/testsuite/g++.dg/ext/has-builtin-1.C
> > @@ -104,6 +104,9 @@
> > #if !__has_builtin (__is_function)
> > # error "__has_builtin (__is_function) failed"
> > #endif
> > +#if !__has_builtin (__is_invocable)
> > +# error "__has_builtin (__is_invocable) failed"
> > +#endif
> > #if !__has_builtin (__is_layout_compatible)
> > # error "__has_builtin (__is_layout_compatible) failed"
> > #endif
> > diff --git a/gcc/testsuite/g++.dg/ext/is_invocable1.C b/gcc/testsuite/g++.dg/ext/is_invocable1.C
> > new file mode 100644
> > index 00000000000..d21ae1d1958
> > --- /dev/null
> > +++ b/gcc/testsuite/g++.dg/ext/is_invocable1.C
> > @@ -0,0 +1,349 @@
> > +// { dg-do compile { target c++11 } }
> > +
> > +#define SA(X) static_assert((X),#X)
> > +
> > +using func_type_v0 = void(*)();
> > +
> > +SA( __is_invocable( func_type_v0 ) );
> > +SA( ! __is_invocable( func_type_v0, int ) );
> > +
> > +using func_type_i0 = int(*)();
> > +
> > +SA( __is_invocable( func_type_i0 ) );
> > +SA( ! __is_invocable( func_type_i0, int ) );
> > +
> > +using func_type_l0 = int&(*)();
> > +
> > +SA( __is_invocable( func_type_l0 ) );
> > +SA( ! __is_invocable( func_type_l0(int) ) );
> > +
> > +using func_type_ii = int(*)(int);
> > +
> > +SA( ! __is_invocable( func_type_ii ) );
> > +SA( __is_invocable( func_type_ii, int ) );
> > +
> > +using func_type_il = int(*)(int&);
> > +
> > +SA( ! __is_invocable( func_type_il ) );
> > +SA( ! __is_invocable( func_type_il, int ) );
> > +SA( __is_invocable( func_type_il, int& ) );
> > +
> > +using func_type_ir = int(*)(int&&);
> > +
> > +SA( ! __is_invocable( func_type_ir ) );
> > +SA( ! __is_invocable( func_type_ir, int& ) );
> > +SA( __is_invocable( func_type_ir, int ) );
> > +SA( __is_invocable( func_type_ir, int&& ) );
> > +
> > +struct A { };
> > +
> > +using mem_type_i = int A::*;
> > +
> > +SA( ! __is_invocable( mem_type_i ) );
> > +SA( ! __is_invocable( mem_type_i, int ) );
> > +SA( ! __is_invocable( mem_type_i, int* ) );
> > +SA( ! __is_invocable( mem_type_i, int& ) );
> > +SA( ! __is_invocable( mem_type_i, int&& ) );
> > +SA( __is_invocable( mem_type_i, A ) );
> > +SA( __is_invocable( mem_type_i, A* ) );
> > +SA( __is_invocable( mem_type_i, A& ) );
> > +SA( __is_invocable( mem_type_i, A&& ) );
> > +SA( __is_invocable( mem_type_i, const A& ) );
> > +SA( ! __is_invocable( mem_type_i, A&, int ) );
> > +
> > +using memfun_type_i = int (A::*)();
> > +
> > +SA( ! __is_invocable( memfun_type_i ) );
> > +SA( ! __is_invocable( memfun_type_i, int ) );
> > +SA( ! __is_invocable( memfun_type_i, int* ) );
> > +SA( ! __is_invocable( memfun_type_i, int& ) );
> > +SA( ! __is_invocable( memfun_type_i, int&& ) );
> > +SA( __is_invocable( memfun_type_i, A ) );
> > +SA( __is_invocable( memfun_type_i, A* ) );
> > +SA( __is_invocable( memfun_type_i, A& ) );
> > +SA( __is_invocable( memfun_type_i, A&& ) );
> > +SA( ! __is_invocable( memfun_type_i, const A& ) );
> > +SA( ! __is_invocable( memfun_type_i, A&, int ) );
> > +
> > +using memfun_type_ic = int (A::*)() const;
> > +
> > +SA( ! __is_invocable( memfun_type_ic ) );
> > +SA( ! __is_invocable( memfun_type_ic, int ) );
> > +SA( ! __is_invocable( memfun_type_ic, int& ) );
> > +SA( __is_invocable( memfun_type_ic, A& ) );
> > +SA( __is_invocable( memfun_type_ic, A* ) );
> > +SA( ! __is_invocable( memfun_type_ic, A&, int ) );
> > +SA( ! __is_invocable( memfun_type_ic, A*, int& ) );
> > +SA( __is_invocable( memfun_type_ic, const A& ) );
> > +SA( __is_invocable( memfun_type_ic, const A* ) );
> > +SA( ! __is_invocable( memfun_type_ic, const A&, int& ) );
> > +SA( ! __is_invocable( memfun_type_ic, const A*, int ) );
> > +
> > +using memfun_type_iic = int& (A::*)(int&) const;
> > +
> > +SA( ! __is_invocable( memfun_type_iic ) );
> > +SA( ! __is_invocable( memfun_type_iic, int ) );
> > +SA( ! __is_invocable( memfun_type_iic, int& ) );
> > +SA( ! __is_invocable( memfun_type_iic, A&, int ) );
> > +SA( __is_invocable( memfun_type_iic, A&, int& ) );
> > +SA( ! __is_invocable( memfun_type_iic, A*, int ) );
> > +SA( __is_invocable( memfun_type_iic, A*, int& ) );
> > +SA( ! __is_invocable( memfun_type_iic, const A&, int ) );
> > +SA( ! __is_invocable( memfun_type_iic, const A&, int&, int ) );
> > +SA( __is_invocable( memfun_type_iic, const A&, int& ) );
> > +SA( __is_invocable( memfun_type_iic, const A*, int& ) );
> > +
> > +struct B {
> > + int& operator()();
> > + long& operator()() const;
> > + bool& operator()(int);
> > +private:
> > + void operator()(int, int);
> > +};
> > +using CB = const B;
> > +
> > +SA( __is_invocable( B ) );
> > +SA( __is_invocable( B& ) );
> > +SA( __is_invocable( B&& ) );
> > +SA( ! __is_invocable( B* ) );
> > +SA( __is_invocable( CB ) );
> > +SA( __is_invocable( CB& ) );
> > +SA( ! __is_invocable( CB* ) );
> > +
> > +SA( __is_invocable( B, int ) );
> > +SA( __is_invocable( B&, int ) );
> > +SA( __is_invocable( B&&, int ) );
> > +SA( ! __is_invocable( B*, int ) );
> > +SA( ! __is_invocable( CB, int ) );
> > +SA( ! __is_invocable( CB&, int ) );
> > +SA( ! __is_invocable( CB*, int ) );
> > +
> > +SA( ! __is_invocable( B, int, int ) );
> > +SA( ! __is_invocable( B&, int, int ) );
> > +SA( ! __is_invocable( B&&, int, int ) );
> > +SA( ! __is_invocable( B*, int, int ) );
> > +SA( ! __is_invocable( CB, int, int ) );
> > +SA( ! __is_invocable( CB&, int, int ) );
> > +SA( ! __is_invocable( CB*, int, int ) );
> > +
> > +struct C : B { int& operator()() = delete; };
> > +using CC = const C;
> > +
> > +SA( ! __is_invocable( C ) );
> > +SA( ! __is_invocable( C& ) );
> > +SA( ! __is_invocable( C&& ) );
> > +SA( ! __is_invocable( C* ) );
> > +SA( ! __is_invocable( CC ) );
> > +SA( ! __is_invocable( CC& ) );
> > +SA( ! __is_invocable( CC* ) );
> > +
> > +struct D { B operator*(); };
> > +using CD = const D;
> > +
> > +SA( ! __is_invocable( D ) );
> > +
> > +struct E { void v(); };
> > +using CE = const E;
> > +
> > +SA( ! __is_invocable( E ) );
> > +SA( ! __is_invocable( void (E::*)() ) );
> > +SA( __is_invocable( void (E::*)(), E ) );
> > +SA( __is_invocable( void (E::*)(), E* ) );
> > +SA( ! __is_invocable( void (E::*)(), CE ) );
> > +
> > +struct F : E {};
> > +using CF = const F;
> > +
> > +SA( ! __is_invocable( F ) );
> > +SA( __is_invocable( void (E::*)(), F ) );
> > +SA( __is_invocable( void (E::*)(), F* ) );
> > +SA( ! __is_invocable( void (E::*)(), CF ) );
> > +
> > +struct G { E operator*(); };
> > +using CG = const G;
> > +
> > +SA( ! __is_invocable( G ) );
> > +SA( __is_invocable( void (E::*)(), G ) );
> > +SA( ! __is_invocable( void (E::*)(), G* ) );
> > +SA( ! __is_invocable( void (E::*)(), CG ) );
> > +
> > +struct H { E& operator*(); };
> > +using CH = const H;
> > +
> > +SA( ! __is_invocable( H ) );
> > +SA( __is_invocable( void (E::*)(), H ) );
> > +SA( ! __is_invocable( void (E::*)(), H* ) );
> > +SA( ! __is_invocable( void (E::*)(), CH ) );
> > +
> > +struct I { E&& operator*(); };
> > +using CI = const I;
> > +
> > +SA( ! __is_invocable( I ) );
> > +SA( __is_invocable( void (E::*)(), I ) );
> > +SA( ! __is_invocable( void (E::*)(), I* ) );
> > +SA( ! __is_invocable( void (E::*)(), CI ) );
> > +
> > +struct K { E* operator*(); };
> > +using CK = const K;
> > +
> > +SA( ! __is_invocable( K ) );
> > +SA( ! __is_invocable( void (E::*)(), K ) );
> > +SA( ! __is_invocable( void (E::*)(), K* ) );
> > +SA( ! __is_invocable( void (E::*)(), CK ) );
> > +
> > +struct L { CE operator*(); };
> > +using CL = const L;
> > +
> > +SA( ! __is_invocable( L ) );
> > +SA( ! __is_invocable( void (E::*)(), L ) );
> > +SA( ! __is_invocable( void (E::*)(), L* ) );
> > +SA( ! __is_invocable( void (E::*)(), CL ) );
> > +
> > +struct M {
> > + int i;
> > +private:
> > + long l;
> > +};
> > +using CM = const M;
> > +
> > +SA( ! __is_invocable( M ) );
> > +SA( ! __is_invocable( M& ) );
> > +SA( ! __is_invocable( M&& ) );
> > +SA( ! __is_invocable( M* ) );
> > +SA( ! __is_invocable( CM ) );
> > +SA( ! __is_invocable( CM& ) );
> > +SA( ! __is_invocable( CM* ) );
> > +
> > +SA( ! __is_invocable( int M::* ) );
> > +SA( __is_invocable( int M::*, M ) );
> > +SA( __is_invocable( int M::*, M& ) );
> > +SA( __is_invocable( int M::*, M&& ) );
> > +SA( __is_invocable( int M::*, M* ) );
> > +SA( __is_invocable( int M::*, CM ) );
> > +SA( __is_invocable( int M::*, CM& ) );
> > +SA( __is_invocable( int M::*, CM* ) );
> > +SA( ! __is_invocable( int M::*, int ) );
> > +
> > +SA( ! __is_invocable( int CM::* ) );
> > +SA( __is_invocable( int CM::*, M ) );
> > +SA( __is_invocable( int CM::*, M& ) );
> > +SA( __is_invocable( int CM::*, M&& ) );
> > +SA( __is_invocable( int CM::*, M* ) );
> > +SA( __is_invocable( int CM::*, CM ) );
> > +SA( __is_invocable( int CM::*, CM& ) );
> > +SA( __is_invocable( int CM::*, CM* ) );
> > +SA( ! __is_invocable( int CM::*, int ) );
> > +
> > +SA( ! __is_invocable( long M::* ) );
> > +SA( __is_invocable( long M::*, M ) );
> > +SA( __is_invocable( long M::*, M& ) );
> > +SA( __is_invocable( long M::*, M&& ) );
> > +SA( __is_invocable( long M::*, M* ) );
> > +SA( __is_invocable( long M::*, CM ) );
> > +SA( __is_invocable( long M::*, CM& ) );
> > +SA( __is_invocable( long M::*, CM* ) );
> > +SA( ! __is_invocable( long M::*, long ) );
> > +
> > +SA( ! __is_invocable( long CM::* ) );
> > +SA( __is_invocable( long CM::*, M ) );
> > +SA( __is_invocable( long CM::*, M& ) );
> > +SA( __is_invocable( long CM::*, M&& ) );
> > +SA( __is_invocable( long CM::*, M* ) );
> > +SA( __is_invocable( long CM::*, CM ) );
> > +SA( __is_invocable( long CM::*, CM& ) );
> > +SA( __is_invocable( long CM::*, CM* ) );
> > +SA( ! __is_invocable( long CM::*, long ) );
> > +
> > +SA( ! __is_invocable( short M::* ) );
> > +SA( __is_invocable( short M::*, M ) );
> > +SA( __is_invocable( short M::*, M& ) );
> > +SA( __is_invocable( short M::*, M&& ) );
> > +SA( __is_invocable( short M::*, M* ) );
> > +SA( __is_invocable( short M::*, CM ) );
> > +SA( __is_invocable( short M::*, CM& ) );
> > +SA( __is_invocable( short M::*, CM* ) );
> > +SA( ! __is_invocable( short M::*, short ) );
> > +
> > +SA( ! __is_invocable( short CM::* ) );
> > +SA( __is_invocable( short CM::*, M ) );
> > +SA( __is_invocable( short CM::*, M& ) );
> > +SA( __is_invocable( short CM::*, M&& ) );
> > +SA( __is_invocable( short CM::*, M* ) );
> > +SA( __is_invocable( short CM::*, CM ) );
> > +SA( __is_invocable( short CM::*, CM& ) );
> > +SA( __is_invocable( short CM::*, CM* ) );
> > +SA( ! __is_invocable( short CM::*, short ) );
> > +
> > +struct N { M operator*(); };
> > +SA( __is_invocable( int M::*, N ) );
> > +SA( ! __is_invocable( int M::*, N* ) );
> > +
> > +struct O { M& operator*(); };
> > +SA( __is_invocable( int M::*, O ) );
> > +SA( ! __is_invocable( int M::*, O* ) );
> > +
> > +struct P { M&& operator*(); };
> > +SA( __is_invocable( int M::*, P ) );
> > +SA( ! __is_invocable( int M::*, P* ) );
> > +
> > +struct Q { M* operator*(); };
> > +SA( ! __is_invocable( int M::*, Q ) );
> > +SA( ! __is_invocable( int M::*, Q* ) );
> > +
> > +struct R { void operator()(int = 0); };
> > +
> > +SA( __is_invocable( R ) );
> > +SA( __is_invocable( R, int ) );
> > +SA( ! __is_invocable( R, int, int ) );
> > +
> > +struct S { void operator()(int, ...); };
> > +
> > +SA( ! __is_invocable( S ) );
> > +SA( __is_invocable( S, int ) );
> > +SA( __is_invocable( S, int, int ) );
> > +SA( __is_invocable( S, int, int, int ) );
> > +
> > +void fn1() {}
> > +
> > +SA( __is_invocable( decltype(fn1) ) );
> > +
> > +void fn2(int arr[10]);
> > +
> > +SA( __is_invocable( decltype(fn2), int[10] ) );
> > +SA( __is_invocable( decltype(fn2), int(&)[10] ) );
> > +SA( __is_invocable( decltype(fn2), int(&&)[10] ) );
> > +SA( ! __is_invocable( decltype(fn2), int(*)[10] ) );
> > +SA( ! __is_invocable( decltype(fn2), int(*&)[10] ) );
> > +SA( ! __is_invocable( decltype(fn2), int(*&&)[10] ) );
> > +SA( __is_invocable( decltype(fn2), int[] ) );
> > +
> > +auto lambda = []() {};
> > +
> > +SA( __is_invocable( decltype(lambda) ) );
> > +
> > +template <typename Func, typename... Args>
> > +struct can_invoke {
> > + static constexpr bool value = __is_invocable( Func, Args... );
> > +};
> > +
> > +SA( can_invoke<decltype(lambda)>::value );
> > +
> > +struct T {
> > + void func() const {}
> > + int data;
> > +};
> > +
> > +SA( __is_invocable( decltype(&T::func)&, T& ) );
> > +SA( __is_invocable( decltype(&T::data)&, T& ) );
> > +
> > +struct U { };
> > +struct V : U { U& operator*() = delete; };
> > +SA( __is_invocable( int U::*, V ) );
> > +
> > +struct W : private U { U& operator*(); };
> > +SA( ! __is_invocable( int U::*, W ) );
> > +
> > +struct X { int m; };
> > +struct Y { X& operator*(); };
> > +struct Z : Y { };
> > +SA( __is_invocable(int X::*, Z) );
> > diff --git a/gcc/testsuite/g++.dg/ext/is_invocable2.C b/gcc/testsuite/g++.dg/ext/is_invocable2.C
> > new file mode 100644
> > index 00000000000..a68aefd3e13
> > --- /dev/null
> > +++ b/gcc/testsuite/g++.dg/ext/is_invocable2.C
> > @@ -0,0 +1,139 @@
> > +// { dg-do compile { target c++11 } }
> > +// __is_invocable should handle std::reference_wrapper correctly.
> > +
> > +#include <functional>
> > +
> > +#define SA(X) static_assert((X),#X)
> > +
> > +using std::reference_wrapper;
> > +
> > +using func_type_v0 = void(*)();
> > +
> > +SA( __is_invocable( reference_wrapper<func_type_v0> ) );
> > +SA( ! __is_invocable( reference_wrapper<func_type_v0>, int ) );
> > +
> > +using func_type_i0 = int(*)();
> > +
> > +SA( __is_invocable( reference_wrapper<func_type_i0> ) );
> > +SA( ! __is_invocable( reference_wrapper<func_type_i0>, int ) );
> > +
> > +using func_type_l0 = int&(*)();
> > +
> > +SA( __is_invocable( reference_wrapper<func_type_l0> ) );
> > +SA( ! __is_invocable( reference_wrapper<func_type_l0(int)> ) );
> > +
> > +using func_type_ii = int(*)(int);
> > +
> > +SA( ! __is_invocable( reference_wrapper<func_type_ii> ) );
> > +SA( __is_invocable( reference_wrapper<func_type_ii>, int ) );
> > +
> > +using func_type_il = int(*)(int&);
> > +
> > +SA( ! __is_invocable( reference_wrapper<func_type_il> ) );
> > +SA( ! __is_invocable( reference_wrapper<func_type_il>, int ) );
> > +SA( __is_invocable( reference_wrapper<func_type_il>, int& ) );
> > +
> > +using func_type_ir = int(*)(int&&);
> > +
> > +SA( ! __is_invocable( reference_wrapper<func_type_ir> ) );
> > +SA( ! __is_invocable( reference_wrapper<func_type_ir>, int& ) );
> > +SA( __is_invocable( reference_wrapper<func_type_ir>, int ) );
> > +SA( __is_invocable( reference_wrapper<func_type_ir>, int&& ) );
> > +
> > +struct A { };
> > +
> > +using mem_type_i = int A::*;
> > +
> > +SA( ! __is_invocable( reference_wrapper<mem_type_i> ) );
> > +SA( ! __is_invocable( reference_wrapper<mem_type_i>, int ) );
> > +SA( ! __is_invocable( reference_wrapper<mem_type_i>, int* ) );
> > +SA( ! __is_invocable( reference_wrapper<mem_type_i>, int& ) );
> > +SA( ! __is_invocable( reference_wrapper<mem_type_i>, int&& ) );
> > +SA( __is_invocable( reference_wrapper<mem_type_i>, A ) );
> > +SA( __is_invocable( reference_wrapper<mem_type_i>, A* ) );
> > +SA( __is_invocable( reference_wrapper<mem_type_i>, A& ) );
> > +SA( __is_invocable( reference_wrapper<mem_type_i>, A&& ) );
> > +
> > +using memfun_type_i = int (A::*)();
> > +
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_i> ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_i>, int ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_i>, int* ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_i>, int& ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_i>, int&& ) );
> > +SA( __is_invocable( reference_wrapper<memfun_type_i>, A ) );
> > +SA( __is_invocable( reference_wrapper<memfun_type_i>, A* ) );
> > +SA( __is_invocable( reference_wrapper<memfun_type_i>, A& ) );
> > +SA( __is_invocable( reference_wrapper<memfun_type_i>, A&& ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_i>, const A& ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_i>, A&, int ) );
> > +
> > +using memfun_type_ic = int (A::*)() const;
> > +
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_ic> ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, int ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, int& ) );
> > +SA( __is_invocable( reference_wrapper<memfun_type_ic>, A& ) );
> > +SA( __is_invocable( reference_wrapper<memfun_type_ic>, A* ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, A&, int ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, A*, int& ) );
> > +SA( __is_invocable( reference_wrapper<memfun_type_ic>, const A& ) );
> > +SA( __is_invocable( reference_wrapper<memfun_type_ic>, const A* ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, const A&, int& ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, const A*, int ) );
> > +
> > +using memfun_type_iic = int& (A::*)(int&) const;
> > +
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_iic> ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, int ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, int& ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, A&, int ) );
> > +SA( __is_invocable( reference_wrapper<memfun_type_iic>, A&, int& ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, A*, int ) );
> > +SA( __is_invocable( reference_wrapper<memfun_type_iic>, A*, int& ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, const A&, int ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, const A&, int&, int ) );
> > +SA( __is_invocable( reference_wrapper<memfun_type_iic>, const A&, int& ) );
> > +SA( __is_invocable( reference_wrapper<memfun_type_iic>, const A*, int& ) );
> > +
> > +struct B {
> > + int& operator()();
> > + long& operator()() const;
> > + bool& operator()(int);
> > +private:
> > + void operator()(int, int);
> > +};
> > +using CB = const B;
> > +
> > +SA( __is_invocable( reference_wrapper<B> ) );
> > +SA( __is_invocable( reference_wrapper<B>& ) );
> > +SA( __is_invocable( reference_wrapper<B>&& ) );
> > +SA( __is_invocable( reference_wrapper<CB> ) );
> > +SA( __is_invocable( reference_wrapper<CB>& ) );
> > +SA( __is_invocable( reference_wrapper<B>, int ) );
> > +SA( ! __is_invocable( reference_wrapper<B>&, int, int ) );
> > +
> > +struct C : B { int& operator()() = delete; };
> > +using CC = const C;
> > +
> > +SA( ! __is_invocable( reference_wrapper<C> ) );
> > +SA( ! __is_invocable( reference_wrapper<C>& ) );
> > +SA( ! __is_invocable( reference_wrapper<C>&& ) );
> > +SA( ! __is_invocable( reference_wrapper<CC> ) );
> > +SA( ! __is_invocable( reference_wrapper<CC>& ) );
> > +
> > +struct D { B operator*(); };
> > +using CD = const D;
> > +
> > +SA( ! __is_invocable( reference_wrapper<D> ) );
> > +SA( ! __is_invocable( reference_wrapper<D>& ) );
> > +SA( ! __is_invocable( reference_wrapper<D>&& ) );
> > +SA( ! __is_invocable( reference_wrapper<D>* ) );
> > +SA( ! __is_invocable( reference_wrapper<D*> ) );
> > +SA( ! __is_invocable( reference_wrapper<D*>* ) );
> > +
> > +std::function<void()> fn = []() {};
> > +auto refwrap = std::ref(fn);
> > +
> > +SA( __is_invocable( decltype(fn) ) );
> > +SA( __is_invocable( decltype(refwrap) ) );
> > diff --git a/gcc/testsuite/g++.dg/ext/is_invocable3.C b/gcc/testsuite/g++.dg/ext/is_invocable3.C
> > new file mode 100644
> > index 00000000000..8699b0a53ca
> > --- /dev/null
> > +++ b/gcc/testsuite/g++.dg/ext/is_invocable3.C
> > @@ -0,0 +1,51 @@
> > +// { dg-do compile { target c++11 } }
> > +// __is_invocable should handle incomplete class correctly.
> > +
> > +#define SA(X) static_assert((X),#X)
> > +
> > +struct Incomplete;
> > +
> > +SA( ! __is_invocable( Incomplete ) ); // { dg-error "incomplete type" }
> > +SA( ! __is_invocable( Incomplete, int ) ); // { dg-error "incomplete type" }
> > +
> > +SA( ! __is_invocable( int, Incomplete, int ) ); // { dg-error "incomplete type" }
> > +SA( ! __is_invocable( int, Incomplete ) ); // { dg-error "incomplete type" }
> > +
> > +SA( ! __is_invocable( Incomplete, Incomplete() ) ); // { dg-error "incomplete type" }
> > +SA( ! __is_invocable( Incomplete, Incomplete(int), int ) ); // { dg-error "incomplete type" }
> > +SA( ! __is_invocable( Incomplete, Incomplete(int, int), int, int ) ); // { dg-error "incomplete type" }
> > +
> > +SA( ! __is_invocable( Incomplete, Incomplete(), int, int ) ); // { dg-error "incomplete type" }
> > +
> > +SA( ! __is_invocable( int(Incomplete), Incomplete ) ); // { dg-error "incomplete type" }
> > +SA( ! __is_invocable( int(int, Incomplete), int, Incomplete ) ); // { dg-error "incomplete type" }
> > +SA( ! __is_invocable( int(int, Incomplete), Incomplete, int ) ); // { dg-error "incomplete type" }
> > +
> > +SA( __is_invocable( int(Incomplete&), Incomplete& ) ); // { dg-bogus "incomplete type" }
> > +SA( __is_invocable( int(int, Incomplete&), int, Incomplete& ) ); // { dg-bogus "incomplete type" }
> > +
> > +SA( __is_invocable( int(Incomplete&&), Incomplete&& ) ); // { dg-bogus "incomplete type" }
> > +SA( __is_invocable( int(int, Incomplete&&), int, Incomplete&& ) ); // { dg-bogus "incomplete type" }
> > +
> > +SA( __is_invocable( int(const Incomplete&&), const Incomplete&& ) ); // { dg-bogus "incomplete type" }
> > +SA( __is_invocable( int(int, const Incomplete&&), int, const Incomplete&& ) ); // { dg-bogus "incomplete type" }
> > +
> > +SA( __is_invocable( int(const Incomplete&), const Incomplete& ) ); // { dg-bogus "incomplete type" }
> > +SA( __is_invocable( int(int, const Incomplete&), int, const Incomplete& ) ); // { dg-bogus "incomplete type" }
> > +
> > +SA( __is_invocable( int(const Incomplete&), Incomplete& ) ); // { dg-bogus "incomplete type" }
> > +SA( __is_invocable( int(int, const Incomplete&), int, Incomplete& ) ); // { dg-bogus "incomplete type" }
> > +
> > +SA( __is_invocable( int Incomplete::*, const Incomplete& ) ); // { dg-bogus "incomplete type" }
> > +SA( ! __is_invocable( void (Incomplete::*)(long&), const Incomplete*, long& ) ); // { dg-bogus "incomplete type" }
> > +SA( __is_invocable( void (Incomplete::*)(long&) const, Incomplete*, long& ) ); // { dg-bogus "incomplete type" }
> > +
> > +template <typename T>
> > +struct Holder { T t; };
> > +
> > +SA( __is_invocable( int(Holder<Incomplete>&), Holder<Incomplete>& ) ); // { dg-bogus "incomplete type" }
> > +
> > +// Define Incomplete, which is now not incomplete.
> > +struct Incomplete { void operator()(); };
> > +
> > +SA( __is_invocable( Incomplete ) ); // { dg-bogus "incomplete type" }
> > diff --git a/gcc/testsuite/g++.dg/ext/is_invocable4.C b/gcc/testsuite/g++.dg/ext/is_invocable4.C
> > new file mode 100644
> > index 00000000000..d1efccf08f8
> > --- /dev/null
> > +++ b/gcc/testsuite/g++.dg/ext/is_invocable4.C
> > @@ -0,0 +1,33 @@
> > +// { dg-do compile { target c++11 } }
> > +// Failed access check should be a substitution failure, not an error.
> > +
> > +#define SA(X) static_assert((X),#X)
> > +
> > +template<bool B>
> > +struct bool_constant { static constexpr bool value = B; };
> > +
> > +template<typename _Fn, typename... _ArgTypes>
> > +struct is_invocable
> > +: public bool_constant<__is_invocable(_Fn, _ArgTypes...)>
> > +{ };
> > +
> > +#if __cpp_variable_templates
> > +template<typename _Fn, typename... _ArgTypes>
> > +constexpr bool is_invocable_v = __is_invocable(_Fn, _ArgTypes...);
> > +#endif
> > +
> > +class Private
> > +{
> > + void operator()() const
> > + {
> > + SA( ! is_invocable<Private>::value );
> > +#if __cpp_variable_templates
> > + SA( ! is_invocable_v<Private> );
> > +#endif
> > + }
> > +};
> > +
> > +SA( ! is_invocable<Private>::value );
> > +#if __cpp_variable_templates
> > +SA( ! is_invocable_v<Private> );
> > +#endif
> > --
> > 2.44.0
> >
> >
>
On Fri, Mar 8, 2024 at 9:17 AM Patrick Palka <ppalka@redhat.com> wrote:
>
> On Wed, 28 Feb 2024, Ken Matsui wrote:
>
> > This patch implements built-in trait for std::is_invocable.
> >
> > gcc/cp/ChangeLog:
> >
> > * cp-trait.def: Define __is_invocable.
> > * constraint.cc (diagnose_trait_expr): Handle CPTK_IS_INVOCABLE.
> > * semantics.cc (trait_expr_value): Likewise.
> > (finish_trait_expr): Likewise.
> > * cp-tree.h (build_invoke): New function.
> > * method.cc (build_invoke): New function.
> >
> > gcc/testsuite/ChangeLog:
> >
> > * g++.dg/ext/has-builtin-1.C: Test existence of __is_invocable.
> > * g++.dg/ext/is_invocable1.C: New test.
> > * g++.dg/ext/is_invocable2.C: New test.
> > * g++.dg/ext/is_invocable3.C: New test.
> > * g++.dg/ext/is_invocable4.C: New test.
>
> Thanks, this looks great! This generic build_invoke function could be
> used for invoke_result etc as well, and it could also cache the built-up
> call across __is_invocable and __is_nothrow_invocable checks on the same
> arguments (which is a common pattern in the standard library). LGTM
>
> >
> > Signed-off-by: Ken Matsui <kmatsui@gcc.gnu.org>
> > ---
> > gcc/cp/constraint.cc | 6 +
> > gcc/cp/cp-trait.def | 1 +
> > gcc/cp/cp-tree.h | 2 +
> > gcc/cp/method.cc | 132 +++++++++
> > gcc/cp/semantics.cc | 4 +
> > gcc/testsuite/g++.dg/ext/has-builtin-1.C | 3 +
> > gcc/testsuite/g++.dg/ext/is_invocable1.C | 349 +++++++++++++++++++++++
> > gcc/testsuite/g++.dg/ext/is_invocable2.C | 139 +++++++++
> > gcc/testsuite/g++.dg/ext/is_invocable3.C | 51 ++++
> > gcc/testsuite/g++.dg/ext/is_invocable4.C | 33 +++
> > 10 files changed, 720 insertions(+)
> > create mode 100644 gcc/testsuite/g++.dg/ext/is_invocable1.C
> > create mode 100644 gcc/testsuite/g++.dg/ext/is_invocable2.C
> > create mode 100644 gcc/testsuite/g++.dg/ext/is_invocable3.C
> > create mode 100644 gcc/testsuite/g++.dg/ext/is_invocable4.C
> >
> > diff --git a/gcc/cp/constraint.cc b/gcc/cp/constraint.cc
> > index 23ea66d9c12..c87b126fdb1 100644
> > --- a/gcc/cp/constraint.cc
> > +++ b/gcc/cp/constraint.cc
> > @@ -3791,6 +3791,12 @@ diagnose_trait_expr (tree expr, tree args)
> > case CPTK_IS_FUNCTION:
> > inform (loc, " %qT is not a function", t1);
> > break;
> > + case CPTK_IS_INVOCABLE:
> > + if (!t2)
> > + inform (loc, " %qT is not invocable", t1);
> > + else
> > + inform (loc, " %qT is not invocable by %qE", t1, t2);
> > + break;
> > case CPTK_IS_LAYOUT_COMPATIBLE:
> > inform (loc, " %qT is not layout compatible with %qT", t1, t2);
> > break;
> > diff --git a/gcc/cp/cp-trait.def b/gcc/cp/cp-trait.def
> > index 85056c8140b..6cb2b55f4ea 100644
> > --- a/gcc/cp/cp-trait.def
> > +++ b/gcc/cp/cp-trait.def
> > @@ -75,6 +75,7 @@ DEFTRAIT_EXPR (IS_EMPTY, "__is_empty", 1)
> > DEFTRAIT_EXPR (IS_ENUM, "__is_enum", 1)
> > DEFTRAIT_EXPR (IS_FINAL, "__is_final", 1)
> > DEFTRAIT_EXPR (IS_FUNCTION, "__is_function", 1)
> > +DEFTRAIT_EXPR (IS_INVOCABLE, "__is_invocable", -1)
> > DEFTRAIT_EXPR (IS_LAYOUT_COMPATIBLE, "__is_layout_compatible", 2)
> > DEFTRAIT_EXPR (IS_LITERAL_TYPE, "__is_literal_type", 1)
> > DEFTRAIT_EXPR (IS_MEMBER_FUNCTION_POINTER, "__is_member_function_pointer", 1)
> > diff --git a/gcc/cp/cp-tree.h b/gcc/cp/cp-tree.h
> > index 334c11396c2..261d3a71faa 100644
> > --- a/gcc/cp/cp-tree.h
> > +++ b/gcc/cp/cp-tree.h
> > @@ -7334,6 +7334,8 @@ extern tree get_copy_assign (tree);
> > extern tree get_default_ctor (tree);
> > extern tree get_dtor (tree, tsubst_flags_t);
> > extern tree build_stub_object (tree);
> > +extern tree build_invoke (tree, const_tree,
> > + tsubst_flags_t);
> > extern tree strip_inheriting_ctors (tree);
> > extern tree inherited_ctor_binfo (tree);
> > extern bool base_ctor_omit_inherited_parms (tree);
> > diff --git a/gcc/cp/method.cc b/gcc/cp/method.cc
> > index 98c10e6a8b5..953f1bed6fc 100644
> > --- a/gcc/cp/method.cc
> > +++ b/gcc/cp/method.cc
> > @@ -1928,6 +1928,138 @@ build_trait_object (tree type)
> > return build_stub_object (type);
> > }
> >
> > +/* [func.require] Build an expression of INVOKE(FN_TYPE, ARG_TYPES...). If the
> > + given is not invocable, returns error_mark_node. */
> > +
> > +tree
> > +build_invoke (tree fn_type, const_tree arg_types, tsubst_flags_t complain)
> > +{
> > + if (fn_type == error_mark_node || arg_types == error_mark_node)
> > + return error_mark_node;
> > +
> > + gcc_assert (TYPE_P (fn_type));
> > + gcc_assert (TREE_CODE (arg_types) == TREE_VEC);
> > +
> > + /* Access check is required to determine if the given is invocable. */
> > + deferring_access_check_sentinel acs (dk_no_deferred);
> > +
> > + /* INVOKE is an unevaluated context. */
> > + cp_unevaluated cp_uneval_guard;
> > +
> > + bool is_ptrdatamem;
> > + bool is_ptrmemfunc;
> > + if (TREE_CODE (fn_type) == REFERENCE_TYPE)
> > + {
> > + tree deref_fn_type = TREE_TYPE (fn_type);
> > + is_ptrdatamem = TYPE_PTRDATAMEM_P (deref_fn_type);
> > + is_ptrmemfunc = TYPE_PTRMEMFUNC_P (deref_fn_type);
> > +
> > + /* Dereference fn_type if it is a pointer to member. */
> > + if (is_ptrdatamem || is_ptrmemfunc)
> > + fn_type = deref_fn_type;
> > + }
> > + else
> > + {
> > + is_ptrdatamem = TYPE_PTRDATAMEM_P (fn_type);
> > + is_ptrmemfunc = TYPE_PTRMEMFUNC_P (fn_type);
> > + }
> > +
> > + if (is_ptrdatamem && TREE_VEC_LENGTH (arg_types) != 1)
> > + /* Only a pointer to data member with one argument is invocable. */
>
> Just one note, if/when build_invoke gets a caller that passes tf_error
> (for e.g. elaborating why is_invocable is false, or why invoke_result
> is ill-formed) these error_mark_node code paths will need to issue
> diagnostics b.
Which function should we use for diagnostics - error, error_at, or
something else? If we opt for error_at, which location information do
we want to use?
>
> > + return error_mark_node;
> > +
> > + if (is_ptrmemfunc && TREE_VEC_LENGTH (arg_types) == 0)
> > + /* A pointer to member function with no arguments is not invocable. */
> > + return error_mark_node;
> > +
> > + /* Construct an expression of a pointer to member. */
> > + tree ptrmem_expr;
> > + if (is_ptrdatamem || is_ptrmemfunc)
> > + {
> > + tree datum_type = TREE_VEC_ELT (arg_types, 0);
> > +
> > + /* datum must be a class type or a reference/pointer to a class type. */
> > + if (TYPE_REF_P (datum_type) || POINTER_TYPE_P (datum_type))
> > + {
> > + if (!CLASS_TYPE_P (TREE_TYPE (datum_type)))
> > + return error_mark_node;
> > + }
> > + else if (!CLASS_TYPE_P (datum_type))
> > + return error_mark_node;
> > +
> > + bool is_refwrap = false;
> > + if (CLASS_TYPE_P (datum_type))
> > + {
> > + /* 1.2 & 1.5: Handle std::reference_wrapper. */
> > + tree datum_decl = TYPE_NAME (TYPE_MAIN_VARIANT (datum_type));
> > + if (decl_in_std_namespace_p (datum_decl))
> > + {
> > + const_tree name = DECL_NAME (datum_decl);
> > + if (name && (id_equal (name, "reference_wrapper")))
> > + {
> > + /* Retrieve T from std::reference_wrapper<T>,
> > + i.e., decltype(datum.get()). */
> > + datum_type = TREE_VEC_ELT (TYPE_TI_ARGS (datum_type), 0);
> > + is_refwrap = true;
> > + }
> > + }
> > + }
> > +
> > + tree datum_expr = build_trait_object (datum_type);
> > + tree fn_expr = build_trait_object (fn_type);
> > + ptrmem_expr = build_m_component_ref (datum_expr, fn_expr, complain);
> > +
> > + if (error_operand_p (ptrmem_expr) && !is_refwrap)
> > + {
> > + tree ptrmem_class_type = TYPE_PTRMEM_CLASS_TYPE (fn_type);
> > + const bool ptrmem_is_base_of_datum =
> > + (NON_UNION_CLASS_TYPE_P (ptrmem_class_type)
> > + && NON_UNION_CLASS_TYPE_P (datum_type)
> > + && (same_type_ignoring_top_level_qualifiers_p (ptrmem_class_type,
> > + datum_type)
> > + || DERIVED_FROM_P (ptrmem_class_type, datum_type)));
> > +
> > + if (!ptrmem_is_base_of_datum)
> > + {
> > + /* 1.3 & 1.6: Try to dereference datum_expr. */
> > + datum_expr = build_x_indirect_ref (UNKNOWN_LOCATION, datum_expr,
> > + RO_UNARY_STAR, NULL_TREE,
> > + complain);
> > + /* Rebuild ptrmem_expr. */
> > + ptrmem_expr = build_m_component_ref (datum_expr, fn_expr,
> > + complain);
> > + }
> > + }
> > + /* 1.1 & 1.4: Otherwise. */
> > +
> > + if (error_operand_p (ptrmem_expr))
> > + return error_mark_node;
> > +
> > + if (is_ptrdatamem)
> > + return ptrmem_expr;
> > + }
> > +
> > + /* Construct expressions for arguments to INVOKE. For a pointer to member
> > + function, the first argument, which is the object, is not arguments to
> > + the function. */
> > + releasing_vec args;
> > + for (int i = is_ptrmemfunc ? 1 : 0; i < TREE_VEC_LENGTH (arg_types); ++i)
> > + {
> > + tree arg_type = TREE_VEC_ELT (arg_types, i);
> > + tree arg = build_trait_object (arg_type);
> > + vec_safe_push (args, arg);
> > + }
> > +
> > + tree invoke_expr;
> > + if (is_ptrmemfunc)
> > + invoke_expr = build_offset_ref_call_from_tree (ptrmem_expr, &args,
> > + complain);
> > + else /* 1.7. */
> > + invoke_expr = finish_call_expr (build_trait_object (fn_type), &args, false,
> > + false, complain);
> > + return invoke_expr;
> > +}
> > +
> > /* Determine which function will be called when looking up NAME in TYPE,
> > called with a single ARGTYPE argument, or no argument if ARGTYPE is
> > null. FLAGS and COMPLAIN are as for build_new_method_call.
> > diff --git a/gcc/cp/semantics.cc b/gcc/cp/semantics.cc
> > index 7242db75248..149c0631d62 100644
> > --- a/gcc/cp/semantics.cc
> > +++ b/gcc/cp/semantics.cc
> > @@ -12467,6 +12467,9 @@ trait_expr_value (cp_trait_kind kind, tree type1, tree type2)
> > case CPTK_IS_FUNCTION:
> > return type_code1 == FUNCTION_TYPE;
> >
> > + case CPTK_IS_INVOCABLE:
> > + return !error_operand_p (build_invoke (type1, type2, tf_none));
> > +
> > case CPTK_IS_LAYOUT_COMPATIBLE:
> > return layout_compatible_type_p (type1, type2);
> >
> > @@ -12682,6 +12685,7 @@ finish_trait_expr (location_t loc, cp_trait_kind kind, tree type1, tree type2)
> > break;
> >
> > case CPTK_IS_CONVERTIBLE:
> > + case CPTK_IS_INVOCABLE:
> > case CPTK_IS_NOTHROW_ASSIGNABLE:
> > case CPTK_IS_NOTHROW_CONSTRUCTIBLE:
> > case CPTK_IS_NOTHROW_CONVERTIBLE:
> > diff --git a/gcc/testsuite/g++.dg/ext/has-builtin-1.C b/gcc/testsuite/g++.dg/ext/has-builtin-1.C
> > index 7f7b27f7aa7..d2a7ebdf25c 100644
> > --- a/gcc/testsuite/g++.dg/ext/has-builtin-1.C
> > +++ b/gcc/testsuite/g++.dg/ext/has-builtin-1.C
> > @@ -104,6 +104,9 @@
> > #if !__has_builtin (__is_function)
> > # error "__has_builtin (__is_function) failed"
> > #endif
> > +#if !__has_builtin (__is_invocable)
> > +# error "__has_builtin (__is_invocable) failed"
> > +#endif
> > #if !__has_builtin (__is_layout_compatible)
> > # error "__has_builtin (__is_layout_compatible) failed"
> > #endif
> > diff --git a/gcc/testsuite/g++.dg/ext/is_invocable1.C b/gcc/testsuite/g++.dg/ext/is_invocable1.C
> > new file mode 100644
> > index 00000000000..d21ae1d1958
> > --- /dev/null
> > +++ b/gcc/testsuite/g++.dg/ext/is_invocable1.C
> > @@ -0,0 +1,349 @@
> > +// { dg-do compile { target c++11 } }
> > +
> > +#define SA(X) static_assert((X),#X)
> > +
> > +using func_type_v0 = void(*)();
> > +
> > +SA( __is_invocable( func_type_v0 ) );
> > +SA( ! __is_invocable( func_type_v0, int ) );
> > +
> > +using func_type_i0 = int(*)();
> > +
> > +SA( __is_invocable( func_type_i0 ) );
> > +SA( ! __is_invocable( func_type_i0, int ) );
> > +
> > +using func_type_l0 = int&(*)();
> > +
> > +SA( __is_invocable( func_type_l0 ) );
> > +SA( ! __is_invocable( func_type_l0(int) ) );
> > +
> > +using func_type_ii = int(*)(int);
> > +
> > +SA( ! __is_invocable( func_type_ii ) );
> > +SA( __is_invocable( func_type_ii, int ) );
> > +
> > +using func_type_il = int(*)(int&);
> > +
> > +SA( ! __is_invocable( func_type_il ) );
> > +SA( ! __is_invocable( func_type_il, int ) );
> > +SA( __is_invocable( func_type_il, int& ) );
> > +
> > +using func_type_ir = int(*)(int&&);
> > +
> > +SA( ! __is_invocable( func_type_ir ) );
> > +SA( ! __is_invocable( func_type_ir, int& ) );
> > +SA( __is_invocable( func_type_ir, int ) );
> > +SA( __is_invocable( func_type_ir, int&& ) );
> > +
> > +struct A { };
> > +
> > +using mem_type_i = int A::*;
> > +
> > +SA( ! __is_invocable( mem_type_i ) );
> > +SA( ! __is_invocable( mem_type_i, int ) );
> > +SA( ! __is_invocable( mem_type_i, int* ) );
> > +SA( ! __is_invocable( mem_type_i, int& ) );
> > +SA( ! __is_invocable( mem_type_i, int&& ) );
> > +SA( __is_invocable( mem_type_i, A ) );
> > +SA( __is_invocable( mem_type_i, A* ) );
> > +SA( __is_invocable( mem_type_i, A& ) );
> > +SA( __is_invocable( mem_type_i, A&& ) );
> > +SA( __is_invocable( mem_type_i, const A& ) );
> > +SA( ! __is_invocable( mem_type_i, A&, int ) );
> > +
> > +using memfun_type_i = int (A::*)();
> > +
> > +SA( ! __is_invocable( memfun_type_i ) );
> > +SA( ! __is_invocable( memfun_type_i, int ) );
> > +SA( ! __is_invocable( memfun_type_i, int* ) );
> > +SA( ! __is_invocable( memfun_type_i, int& ) );
> > +SA( ! __is_invocable( memfun_type_i, int&& ) );
> > +SA( __is_invocable( memfun_type_i, A ) );
> > +SA( __is_invocable( memfun_type_i, A* ) );
> > +SA( __is_invocable( memfun_type_i, A& ) );
> > +SA( __is_invocable( memfun_type_i, A&& ) );
> > +SA( ! __is_invocable( memfun_type_i, const A& ) );
> > +SA( ! __is_invocable( memfun_type_i, A&, int ) );
> > +
> > +using memfun_type_ic = int (A::*)() const;
> > +
> > +SA( ! __is_invocable( memfun_type_ic ) );
> > +SA( ! __is_invocable( memfun_type_ic, int ) );
> > +SA( ! __is_invocable( memfun_type_ic, int& ) );
> > +SA( __is_invocable( memfun_type_ic, A& ) );
> > +SA( __is_invocable( memfun_type_ic, A* ) );
> > +SA( ! __is_invocable( memfun_type_ic, A&, int ) );
> > +SA( ! __is_invocable( memfun_type_ic, A*, int& ) );
> > +SA( __is_invocable( memfun_type_ic, const A& ) );
> > +SA( __is_invocable( memfun_type_ic, const A* ) );
> > +SA( ! __is_invocable( memfun_type_ic, const A&, int& ) );
> > +SA( ! __is_invocable( memfun_type_ic, const A*, int ) );
> > +
> > +using memfun_type_iic = int& (A::*)(int&) const;
> > +
> > +SA( ! __is_invocable( memfun_type_iic ) );
> > +SA( ! __is_invocable( memfun_type_iic, int ) );
> > +SA( ! __is_invocable( memfun_type_iic, int& ) );
> > +SA( ! __is_invocable( memfun_type_iic, A&, int ) );
> > +SA( __is_invocable( memfun_type_iic, A&, int& ) );
> > +SA( ! __is_invocable( memfun_type_iic, A*, int ) );
> > +SA( __is_invocable( memfun_type_iic, A*, int& ) );
> > +SA( ! __is_invocable( memfun_type_iic, const A&, int ) );
> > +SA( ! __is_invocable( memfun_type_iic, const A&, int&, int ) );
> > +SA( __is_invocable( memfun_type_iic, const A&, int& ) );
> > +SA( __is_invocable( memfun_type_iic, const A*, int& ) );
> > +
> > +struct B {
> > + int& operator()();
> > + long& operator()() const;
> > + bool& operator()(int);
> > +private:
> > + void operator()(int, int);
> > +};
> > +using CB = const B;
> > +
> > +SA( __is_invocable( B ) );
> > +SA( __is_invocable( B& ) );
> > +SA( __is_invocable( B&& ) );
> > +SA( ! __is_invocable( B* ) );
> > +SA( __is_invocable( CB ) );
> > +SA( __is_invocable( CB& ) );
> > +SA( ! __is_invocable( CB* ) );
> > +
> > +SA( __is_invocable( B, int ) );
> > +SA( __is_invocable( B&, int ) );
> > +SA( __is_invocable( B&&, int ) );
> > +SA( ! __is_invocable( B*, int ) );
> > +SA( ! __is_invocable( CB, int ) );
> > +SA( ! __is_invocable( CB&, int ) );
> > +SA( ! __is_invocable( CB*, int ) );
> > +
> > +SA( ! __is_invocable( B, int, int ) );
> > +SA( ! __is_invocable( B&, int, int ) );
> > +SA( ! __is_invocable( B&&, int, int ) );
> > +SA( ! __is_invocable( B*, int, int ) );
> > +SA( ! __is_invocable( CB, int, int ) );
> > +SA( ! __is_invocable( CB&, int, int ) );
> > +SA( ! __is_invocable( CB*, int, int ) );
> > +
> > +struct C : B { int& operator()() = delete; };
> > +using CC = const C;
> > +
> > +SA( ! __is_invocable( C ) );
> > +SA( ! __is_invocable( C& ) );
> > +SA( ! __is_invocable( C&& ) );
> > +SA( ! __is_invocable( C* ) );
> > +SA( ! __is_invocable( CC ) );
> > +SA( ! __is_invocable( CC& ) );
> > +SA( ! __is_invocable( CC* ) );
> > +
> > +struct D { B operator*(); };
> > +using CD = const D;
> > +
> > +SA( ! __is_invocable( D ) );
> > +
> > +struct E { void v(); };
> > +using CE = const E;
> > +
> > +SA( ! __is_invocable( E ) );
> > +SA( ! __is_invocable( void (E::*)() ) );
> > +SA( __is_invocable( void (E::*)(), E ) );
> > +SA( __is_invocable( void (E::*)(), E* ) );
> > +SA( ! __is_invocable( void (E::*)(), CE ) );
> > +
> > +struct F : E {};
> > +using CF = const F;
> > +
> > +SA( ! __is_invocable( F ) );
> > +SA( __is_invocable( void (E::*)(), F ) );
> > +SA( __is_invocable( void (E::*)(), F* ) );
> > +SA( ! __is_invocable( void (E::*)(), CF ) );
> > +
> > +struct G { E operator*(); };
> > +using CG = const G;
> > +
> > +SA( ! __is_invocable( G ) );
> > +SA( __is_invocable( void (E::*)(), G ) );
> > +SA( ! __is_invocable( void (E::*)(), G* ) );
> > +SA( ! __is_invocable( void (E::*)(), CG ) );
> > +
> > +struct H { E& operator*(); };
> > +using CH = const H;
> > +
> > +SA( ! __is_invocable( H ) );
> > +SA( __is_invocable( void (E::*)(), H ) );
> > +SA( ! __is_invocable( void (E::*)(), H* ) );
> > +SA( ! __is_invocable( void (E::*)(), CH ) );
> > +
> > +struct I { E&& operator*(); };
> > +using CI = const I;
> > +
> > +SA( ! __is_invocable( I ) );
> > +SA( __is_invocable( void (E::*)(), I ) );
> > +SA( ! __is_invocable( void (E::*)(), I* ) );
> > +SA( ! __is_invocable( void (E::*)(), CI ) );
> > +
> > +struct K { E* operator*(); };
> > +using CK = const K;
> > +
> > +SA( ! __is_invocable( K ) );
> > +SA( ! __is_invocable( void (E::*)(), K ) );
> > +SA( ! __is_invocable( void (E::*)(), K* ) );
> > +SA( ! __is_invocable( void (E::*)(), CK ) );
> > +
> > +struct L { CE operator*(); };
> > +using CL = const L;
> > +
> > +SA( ! __is_invocable( L ) );
> > +SA( ! __is_invocable( void (E::*)(), L ) );
> > +SA( ! __is_invocable( void (E::*)(), L* ) );
> > +SA( ! __is_invocable( void (E::*)(), CL ) );
> > +
> > +struct M {
> > + int i;
> > +private:
> > + long l;
> > +};
> > +using CM = const M;
> > +
> > +SA( ! __is_invocable( M ) );
> > +SA( ! __is_invocable( M& ) );
> > +SA( ! __is_invocable( M&& ) );
> > +SA( ! __is_invocable( M* ) );
> > +SA( ! __is_invocable( CM ) );
> > +SA( ! __is_invocable( CM& ) );
> > +SA( ! __is_invocable( CM* ) );
> > +
> > +SA( ! __is_invocable( int M::* ) );
> > +SA( __is_invocable( int M::*, M ) );
> > +SA( __is_invocable( int M::*, M& ) );
> > +SA( __is_invocable( int M::*, M&& ) );
> > +SA( __is_invocable( int M::*, M* ) );
> > +SA( __is_invocable( int M::*, CM ) );
> > +SA( __is_invocable( int M::*, CM& ) );
> > +SA( __is_invocable( int M::*, CM* ) );
> > +SA( ! __is_invocable( int M::*, int ) );
> > +
> > +SA( ! __is_invocable( int CM::* ) );
> > +SA( __is_invocable( int CM::*, M ) );
> > +SA( __is_invocable( int CM::*, M& ) );
> > +SA( __is_invocable( int CM::*, M&& ) );
> > +SA( __is_invocable( int CM::*, M* ) );
> > +SA( __is_invocable( int CM::*, CM ) );
> > +SA( __is_invocable( int CM::*, CM& ) );
> > +SA( __is_invocable( int CM::*, CM* ) );
> > +SA( ! __is_invocable( int CM::*, int ) );
> > +
> > +SA( ! __is_invocable( long M::* ) );
> > +SA( __is_invocable( long M::*, M ) );
> > +SA( __is_invocable( long M::*, M& ) );
> > +SA( __is_invocable( long M::*, M&& ) );
> > +SA( __is_invocable( long M::*, M* ) );
> > +SA( __is_invocable( long M::*, CM ) );
> > +SA( __is_invocable( long M::*, CM& ) );
> > +SA( __is_invocable( long M::*, CM* ) );
> > +SA( ! __is_invocable( long M::*, long ) );
> > +
> > +SA( ! __is_invocable( long CM::* ) );
> > +SA( __is_invocable( long CM::*, M ) );
> > +SA( __is_invocable( long CM::*, M& ) );
> > +SA( __is_invocable( long CM::*, M&& ) );
> > +SA( __is_invocable( long CM::*, M* ) );
> > +SA( __is_invocable( long CM::*, CM ) );
> > +SA( __is_invocable( long CM::*, CM& ) );
> > +SA( __is_invocable( long CM::*, CM* ) );
> > +SA( ! __is_invocable( long CM::*, long ) );
> > +
> > +SA( ! __is_invocable( short M::* ) );
> > +SA( __is_invocable( short M::*, M ) );
> > +SA( __is_invocable( short M::*, M& ) );
> > +SA( __is_invocable( short M::*, M&& ) );
> > +SA( __is_invocable( short M::*, M* ) );
> > +SA( __is_invocable( short M::*, CM ) );
> > +SA( __is_invocable( short M::*, CM& ) );
> > +SA( __is_invocable( short M::*, CM* ) );
> > +SA( ! __is_invocable( short M::*, short ) );
> > +
> > +SA( ! __is_invocable( short CM::* ) );
> > +SA( __is_invocable( short CM::*, M ) );
> > +SA( __is_invocable( short CM::*, M& ) );
> > +SA( __is_invocable( short CM::*, M&& ) );
> > +SA( __is_invocable( short CM::*, M* ) );
> > +SA( __is_invocable( short CM::*, CM ) );
> > +SA( __is_invocable( short CM::*, CM& ) );
> > +SA( __is_invocable( short CM::*, CM* ) );
> > +SA( ! __is_invocable( short CM::*, short ) );
> > +
> > +struct N { M operator*(); };
> > +SA( __is_invocable( int M::*, N ) );
> > +SA( ! __is_invocable( int M::*, N* ) );
> > +
> > +struct O { M& operator*(); };
> > +SA( __is_invocable( int M::*, O ) );
> > +SA( ! __is_invocable( int M::*, O* ) );
> > +
> > +struct P { M&& operator*(); };
> > +SA( __is_invocable( int M::*, P ) );
> > +SA( ! __is_invocable( int M::*, P* ) );
> > +
> > +struct Q { M* operator*(); };
> > +SA( ! __is_invocable( int M::*, Q ) );
> > +SA( ! __is_invocable( int M::*, Q* ) );
> > +
> > +struct R { void operator()(int = 0); };
> > +
> > +SA( __is_invocable( R ) );
> > +SA( __is_invocable( R, int ) );
> > +SA( ! __is_invocable( R, int, int ) );
> > +
> > +struct S { void operator()(int, ...); };
> > +
> > +SA( ! __is_invocable( S ) );
> > +SA( __is_invocable( S, int ) );
> > +SA( __is_invocable( S, int, int ) );
> > +SA( __is_invocable( S, int, int, int ) );
> > +
> > +void fn1() {}
> > +
> > +SA( __is_invocable( decltype(fn1) ) );
> > +
> > +void fn2(int arr[10]);
> > +
> > +SA( __is_invocable( decltype(fn2), int[10] ) );
> > +SA( __is_invocable( decltype(fn2), int(&)[10] ) );
> > +SA( __is_invocable( decltype(fn2), int(&&)[10] ) );
> > +SA( ! __is_invocable( decltype(fn2), int(*)[10] ) );
> > +SA( ! __is_invocable( decltype(fn2), int(*&)[10] ) );
> > +SA( ! __is_invocable( decltype(fn2), int(*&&)[10] ) );
> > +SA( __is_invocable( decltype(fn2), int[] ) );
> > +
> > +auto lambda = []() {};
> > +
> > +SA( __is_invocable( decltype(lambda) ) );
> > +
> > +template <typename Func, typename... Args>
> > +struct can_invoke {
> > + static constexpr bool value = __is_invocable( Func, Args... );
> > +};
> > +
> > +SA( can_invoke<decltype(lambda)>::value );
> > +
> > +struct T {
> > + void func() const {}
> > + int data;
> > +};
> > +
> > +SA( __is_invocable( decltype(&T::func)&, T& ) );
> > +SA( __is_invocable( decltype(&T::data)&, T& ) );
> > +
> > +struct U { };
> > +struct V : U { U& operator*() = delete; };
> > +SA( __is_invocable( int U::*, V ) );
> > +
> > +struct W : private U { U& operator*(); };
> > +SA( ! __is_invocable( int U::*, W ) );
> > +
> > +struct X { int m; };
> > +struct Y { X& operator*(); };
> > +struct Z : Y { };
> > +SA( __is_invocable(int X::*, Z) );
> > diff --git a/gcc/testsuite/g++.dg/ext/is_invocable2.C b/gcc/testsuite/g++.dg/ext/is_invocable2.C
> > new file mode 100644
> > index 00000000000..a68aefd3e13
> > --- /dev/null
> > +++ b/gcc/testsuite/g++.dg/ext/is_invocable2.C
> > @@ -0,0 +1,139 @@
> > +// { dg-do compile { target c++11 } }
> > +// __is_invocable should handle std::reference_wrapper correctly.
> > +
> > +#include <functional>
> > +
> > +#define SA(X) static_assert((X),#X)
> > +
> > +using std::reference_wrapper;
> > +
> > +using func_type_v0 = void(*)();
> > +
> > +SA( __is_invocable( reference_wrapper<func_type_v0> ) );
> > +SA( ! __is_invocable( reference_wrapper<func_type_v0>, int ) );
> > +
> > +using func_type_i0 = int(*)();
> > +
> > +SA( __is_invocable( reference_wrapper<func_type_i0> ) );
> > +SA( ! __is_invocable( reference_wrapper<func_type_i0>, int ) );
> > +
> > +using func_type_l0 = int&(*)();
> > +
> > +SA( __is_invocable( reference_wrapper<func_type_l0> ) );
> > +SA( ! __is_invocable( reference_wrapper<func_type_l0(int)> ) );
> > +
> > +using func_type_ii = int(*)(int);
> > +
> > +SA( ! __is_invocable( reference_wrapper<func_type_ii> ) );
> > +SA( __is_invocable( reference_wrapper<func_type_ii>, int ) );
> > +
> > +using func_type_il = int(*)(int&);
> > +
> > +SA( ! __is_invocable( reference_wrapper<func_type_il> ) );
> > +SA( ! __is_invocable( reference_wrapper<func_type_il>, int ) );
> > +SA( __is_invocable( reference_wrapper<func_type_il>, int& ) );
> > +
> > +using func_type_ir = int(*)(int&&);
> > +
> > +SA( ! __is_invocable( reference_wrapper<func_type_ir> ) );
> > +SA( ! __is_invocable( reference_wrapper<func_type_ir>, int& ) );
> > +SA( __is_invocable( reference_wrapper<func_type_ir>, int ) );
> > +SA( __is_invocable( reference_wrapper<func_type_ir>, int&& ) );
> > +
> > +struct A { };
> > +
> > +using mem_type_i = int A::*;
> > +
> > +SA( ! __is_invocable( reference_wrapper<mem_type_i> ) );
> > +SA( ! __is_invocable( reference_wrapper<mem_type_i>, int ) );
> > +SA( ! __is_invocable( reference_wrapper<mem_type_i>, int* ) );
> > +SA( ! __is_invocable( reference_wrapper<mem_type_i>, int& ) );
> > +SA( ! __is_invocable( reference_wrapper<mem_type_i>, int&& ) );
> > +SA( __is_invocable( reference_wrapper<mem_type_i>, A ) );
> > +SA( __is_invocable( reference_wrapper<mem_type_i>, A* ) );
> > +SA( __is_invocable( reference_wrapper<mem_type_i>, A& ) );
> > +SA( __is_invocable( reference_wrapper<mem_type_i>, A&& ) );
> > +
> > +using memfun_type_i = int (A::*)();
> > +
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_i> ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_i>, int ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_i>, int* ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_i>, int& ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_i>, int&& ) );
> > +SA( __is_invocable( reference_wrapper<memfun_type_i>, A ) );
> > +SA( __is_invocable( reference_wrapper<memfun_type_i>, A* ) );
> > +SA( __is_invocable( reference_wrapper<memfun_type_i>, A& ) );
> > +SA( __is_invocable( reference_wrapper<memfun_type_i>, A&& ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_i>, const A& ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_i>, A&, int ) );
> > +
> > +using memfun_type_ic = int (A::*)() const;
> > +
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_ic> ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, int ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, int& ) );
> > +SA( __is_invocable( reference_wrapper<memfun_type_ic>, A& ) );
> > +SA( __is_invocable( reference_wrapper<memfun_type_ic>, A* ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, A&, int ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, A*, int& ) );
> > +SA( __is_invocable( reference_wrapper<memfun_type_ic>, const A& ) );
> > +SA( __is_invocable( reference_wrapper<memfun_type_ic>, const A* ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, const A&, int& ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, const A*, int ) );
> > +
> > +using memfun_type_iic = int& (A::*)(int&) const;
> > +
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_iic> ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, int ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, int& ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, A&, int ) );
> > +SA( __is_invocable( reference_wrapper<memfun_type_iic>, A&, int& ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, A*, int ) );
> > +SA( __is_invocable( reference_wrapper<memfun_type_iic>, A*, int& ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, const A&, int ) );
> > +SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, const A&, int&, int ) );
> > +SA( __is_invocable( reference_wrapper<memfun_type_iic>, const A&, int& ) );
> > +SA( __is_invocable( reference_wrapper<memfun_type_iic>, const A*, int& ) );
> > +
> > +struct B {
> > + int& operator()();
> > + long& operator()() const;
> > + bool& operator()(int);
> > +private:
> > + void operator()(int, int);
> > +};
> > +using CB = const B;
> > +
> > +SA( __is_invocable( reference_wrapper<B> ) );
> > +SA( __is_invocable( reference_wrapper<B>& ) );
> > +SA( __is_invocable( reference_wrapper<B>&& ) );
> > +SA( __is_invocable( reference_wrapper<CB> ) );
> > +SA( __is_invocable( reference_wrapper<CB>& ) );
> > +SA( __is_invocable( reference_wrapper<B>, int ) );
> > +SA( ! __is_invocable( reference_wrapper<B>&, int, int ) );
> > +
> > +struct C : B { int& operator()() = delete; };
> > +using CC = const C;
> > +
> > +SA( ! __is_invocable( reference_wrapper<C> ) );
> > +SA( ! __is_invocable( reference_wrapper<C>& ) );
> > +SA( ! __is_invocable( reference_wrapper<C>&& ) );
> > +SA( ! __is_invocable( reference_wrapper<CC> ) );
> > +SA( ! __is_invocable( reference_wrapper<CC>& ) );
> > +
> > +struct D { B operator*(); };
> > +using CD = const D;
> > +
> > +SA( ! __is_invocable( reference_wrapper<D> ) );
> > +SA( ! __is_invocable( reference_wrapper<D>& ) );
> > +SA( ! __is_invocable( reference_wrapper<D>&& ) );
> > +SA( ! __is_invocable( reference_wrapper<D>* ) );
> > +SA( ! __is_invocable( reference_wrapper<D*> ) );
> > +SA( ! __is_invocable( reference_wrapper<D*>* ) );
> > +
> > +std::function<void()> fn = []() {};
> > +auto refwrap = std::ref(fn);
> > +
> > +SA( __is_invocable( decltype(fn) ) );
> > +SA( __is_invocable( decltype(refwrap) ) );
> > diff --git a/gcc/testsuite/g++.dg/ext/is_invocable3.C b/gcc/testsuite/g++.dg/ext/is_invocable3.C
> > new file mode 100644
> > index 00000000000..8699b0a53ca
> > --- /dev/null
> > +++ b/gcc/testsuite/g++.dg/ext/is_invocable3.C
> > @@ -0,0 +1,51 @@
> > +// { dg-do compile { target c++11 } }
> > +// __is_invocable should handle incomplete class correctly.
> > +
> > +#define SA(X) static_assert((X),#X)
> > +
> > +struct Incomplete;
> > +
> > +SA( ! __is_invocable( Incomplete ) ); // { dg-error "incomplete type" }
> > +SA( ! __is_invocable( Incomplete, int ) ); // { dg-error "incomplete type" }
> > +
> > +SA( ! __is_invocable( int, Incomplete, int ) ); // { dg-error "incomplete type" }
> > +SA( ! __is_invocable( int, Incomplete ) ); // { dg-error "incomplete type" }
> > +
> > +SA( ! __is_invocable( Incomplete, Incomplete() ) ); // { dg-error "incomplete type" }
> > +SA( ! __is_invocable( Incomplete, Incomplete(int), int ) ); // { dg-error "incomplete type" }
> > +SA( ! __is_invocable( Incomplete, Incomplete(int, int), int, int ) ); // { dg-error "incomplete type" }
> > +
> > +SA( ! __is_invocable( Incomplete, Incomplete(), int, int ) ); // { dg-error "incomplete type" }
> > +
> > +SA( ! __is_invocable( int(Incomplete), Incomplete ) ); // { dg-error "incomplete type" }
> > +SA( ! __is_invocable( int(int, Incomplete), int, Incomplete ) ); // { dg-error "incomplete type" }
> > +SA( ! __is_invocable( int(int, Incomplete), Incomplete, int ) ); // { dg-error "incomplete type" }
> > +
> > +SA( __is_invocable( int(Incomplete&), Incomplete& ) ); // { dg-bogus "incomplete type" }
> > +SA( __is_invocable( int(int, Incomplete&), int, Incomplete& ) ); // { dg-bogus "incomplete type" }
> > +
> > +SA( __is_invocable( int(Incomplete&&), Incomplete&& ) ); // { dg-bogus "incomplete type" }
> > +SA( __is_invocable( int(int, Incomplete&&), int, Incomplete&& ) ); // { dg-bogus "incomplete type" }
> > +
> > +SA( __is_invocable( int(const Incomplete&&), const Incomplete&& ) ); // { dg-bogus "incomplete type" }
> > +SA( __is_invocable( int(int, const Incomplete&&), int, const Incomplete&& ) ); // { dg-bogus "incomplete type" }
> > +
> > +SA( __is_invocable( int(const Incomplete&), const Incomplete& ) ); // { dg-bogus "incomplete type" }
> > +SA( __is_invocable( int(int, const Incomplete&), int, const Incomplete& ) ); // { dg-bogus "incomplete type" }
> > +
> > +SA( __is_invocable( int(const Incomplete&), Incomplete& ) ); // { dg-bogus "incomplete type" }
> > +SA( __is_invocable( int(int, const Incomplete&), int, Incomplete& ) ); // { dg-bogus "incomplete type" }
> > +
> > +SA( __is_invocable( int Incomplete::*, const Incomplete& ) ); // { dg-bogus "incomplete type" }
> > +SA( ! __is_invocable( void (Incomplete::*)(long&), const Incomplete*, long& ) ); // { dg-bogus "incomplete type" }
> > +SA( __is_invocable( void (Incomplete::*)(long&) const, Incomplete*, long& ) ); // { dg-bogus "incomplete type" }
> > +
> > +template <typename T>
> > +struct Holder { T t; };
> > +
> > +SA( __is_invocable( int(Holder<Incomplete>&), Holder<Incomplete>& ) ); // { dg-bogus "incomplete type" }
> > +
> > +// Define Incomplete, which is now not incomplete.
> > +struct Incomplete { void operator()(); };
> > +
> > +SA( __is_invocable( Incomplete ) ); // { dg-bogus "incomplete type" }
> > diff --git a/gcc/testsuite/g++.dg/ext/is_invocable4.C b/gcc/testsuite/g++.dg/ext/is_invocable4.C
> > new file mode 100644
> > index 00000000000..d1efccf08f8
> > --- /dev/null
> > +++ b/gcc/testsuite/g++.dg/ext/is_invocable4.C
> > @@ -0,0 +1,33 @@
> > +// { dg-do compile { target c++11 } }
> > +// Failed access check should be a substitution failure, not an error.
> > +
> > +#define SA(X) static_assert((X),#X)
> > +
> > +template<bool B>
> > +struct bool_constant { static constexpr bool value = B; };
> > +
> > +template<typename _Fn, typename... _ArgTypes>
> > +struct is_invocable
> > +: public bool_constant<__is_invocable(_Fn, _ArgTypes...)>
> > +{ };
> > +
> > +#if __cpp_variable_templates
> > +template<typename _Fn, typename... _ArgTypes>
> > +constexpr bool is_invocable_v = __is_invocable(_Fn, _ArgTypes...);
> > +#endif
> > +
> > +class Private
> > +{
> > + void operator()() const
> > + {
> > + SA( ! is_invocable<Private>::value );
> > +#if __cpp_variable_templates
> > + SA( ! is_invocable_v<Private> );
> > +#endif
> > + }
> > +};
> > +
> > +SA( ! is_invocable<Private>::value );
> > +#if __cpp_variable_templates
> > +SA( ! is_invocable_v<Private> );
> > +#endif
> > --
> > 2.44.0
> >
> >
>
On Thu, Mar 14, 2024 at 6:53 PM Ken Matsui <kmatsui@cs.washington.edu> wrote:
>
> On Fri, Mar 8, 2024 at 9:17 AM Patrick Palka <ppalka@redhat.com> wrote:
> >
> > On Wed, 28 Feb 2024, Ken Matsui wrote:
> >
> > > This patch implements built-in trait for std::is_invocable.
> > >
> > > gcc/cp/ChangeLog:
> > >
> > > * cp-trait.def: Define __is_invocable.
> > > * constraint.cc (diagnose_trait_expr): Handle CPTK_IS_INVOCABLE.
> > > * semantics.cc (trait_expr_value): Likewise.
> > > (finish_trait_expr): Likewise.
> > > * cp-tree.h (build_invoke): New function.
> > > * method.cc (build_invoke): New function.
> > >
> > > gcc/testsuite/ChangeLog:
> > >
> > > * g++.dg/ext/has-builtin-1.C: Test existence of __is_invocable.
> > > * g++.dg/ext/is_invocable1.C: New test.
> > > * g++.dg/ext/is_invocable2.C: New test.
> > > * g++.dg/ext/is_invocable3.C: New test.
> > > * g++.dg/ext/is_invocable4.C: New test.
> >
> > Thanks, this looks great! This generic build_invoke function could be
> > used for invoke_result etc as well, and it could also cache the built-up
> > call across __is_invocable and __is_nothrow_invocable checks on the same
> > arguments (which is a common pattern in the standard library). LGTM
> >
> > >
> > > Signed-off-by: Ken Matsui <kmatsui@gcc.gnu.org>
> > > ---
> > > gcc/cp/constraint.cc | 6 +
> > > gcc/cp/cp-trait.def | 1 +
> > > gcc/cp/cp-tree.h | 2 +
> > > gcc/cp/method.cc | 132 +++++++++
> > > gcc/cp/semantics.cc | 4 +
> > > gcc/testsuite/g++.dg/ext/has-builtin-1.C | 3 +
> > > gcc/testsuite/g++.dg/ext/is_invocable1.C | 349 +++++++++++++++++++++++
> > > gcc/testsuite/g++.dg/ext/is_invocable2.C | 139 +++++++++
> > > gcc/testsuite/g++.dg/ext/is_invocable3.C | 51 ++++
> > > gcc/testsuite/g++.dg/ext/is_invocable4.C | 33 +++
> > > 10 files changed, 720 insertions(+)
> > > create mode 100644 gcc/testsuite/g++.dg/ext/is_invocable1.C
> > > create mode 100644 gcc/testsuite/g++.dg/ext/is_invocable2.C
> > > create mode 100644 gcc/testsuite/g++.dg/ext/is_invocable3.C
> > > create mode 100644 gcc/testsuite/g++.dg/ext/is_invocable4.C
> > >
> > > diff --git a/gcc/cp/constraint.cc b/gcc/cp/constraint.cc
> > > index 23ea66d9c12..c87b126fdb1 100644
> > > --- a/gcc/cp/constraint.cc
> > > +++ b/gcc/cp/constraint.cc
> > > @@ -3791,6 +3791,12 @@ diagnose_trait_expr (tree expr, tree args)
> > > case CPTK_IS_FUNCTION:
> > > inform (loc, " %qT is not a function", t1);
> > > break;
> > > + case CPTK_IS_INVOCABLE:
> > > + if (!t2)
> > > + inform (loc, " %qT is not invocable", t1);
> > > + else
> > > + inform (loc, " %qT is not invocable by %qE", t1, t2);
> > > + break;
> > > case CPTK_IS_LAYOUT_COMPATIBLE:
> > > inform (loc, " %qT is not layout compatible with %qT", t1, t2);
> > > break;
> > > diff --git a/gcc/cp/cp-trait.def b/gcc/cp/cp-trait.def
> > > index 85056c8140b..6cb2b55f4ea 100644
> > > --- a/gcc/cp/cp-trait.def
> > > +++ b/gcc/cp/cp-trait.def
> > > @@ -75,6 +75,7 @@ DEFTRAIT_EXPR (IS_EMPTY, "__is_empty", 1)
> > > DEFTRAIT_EXPR (IS_ENUM, "__is_enum", 1)
> > > DEFTRAIT_EXPR (IS_FINAL, "__is_final", 1)
> > > DEFTRAIT_EXPR (IS_FUNCTION, "__is_function", 1)
> > > +DEFTRAIT_EXPR (IS_INVOCABLE, "__is_invocable", -1)
> > > DEFTRAIT_EXPR (IS_LAYOUT_COMPATIBLE, "__is_layout_compatible", 2)
> > > DEFTRAIT_EXPR (IS_LITERAL_TYPE, "__is_literal_type", 1)
> > > DEFTRAIT_EXPR (IS_MEMBER_FUNCTION_POINTER, "__is_member_function_pointer", 1)
> > > diff --git a/gcc/cp/cp-tree.h b/gcc/cp/cp-tree.h
> > > index 334c11396c2..261d3a71faa 100644
> > > --- a/gcc/cp/cp-tree.h
> > > +++ b/gcc/cp/cp-tree.h
> > > @@ -7334,6 +7334,8 @@ extern tree get_copy_assign (tree);
> > > extern tree get_default_ctor (tree);
> > > extern tree get_dtor (tree, tsubst_flags_t);
> > > extern tree build_stub_object (tree);
> > > +extern tree build_invoke (tree, const_tree,
> > > + tsubst_flags_t);
> > > extern tree strip_inheriting_ctors (tree);
> > > extern tree inherited_ctor_binfo (tree);
> > > extern bool base_ctor_omit_inherited_parms (tree);
> > > diff --git a/gcc/cp/method.cc b/gcc/cp/method.cc
> > > index 98c10e6a8b5..953f1bed6fc 100644
> > > --- a/gcc/cp/method.cc
> > > +++ b/gcc/cp/method.cc
> > > @@ -1928,6 +1928,138 @@ build_trait_object (tree type)
> > > return build_stub_object (type);
> > > }
> > >
> > > +/* [func.require] Build an expression of INVOKE(FN_TYPE, ARG_TYPES...). If the
> > > + given is not invocable, returns error_mark_node. */
> > > +
> > > +tree
> > > +build_invoke (tree fn_type, const_tree arg_types, tsubst_flags_t complain)
> > > +{
> > > + if (fn_type == error_mark_node || arg_types == error_mark_node)
> > > + return error_mark_node;
> > > +
> > > + gcc_assert (TYPE_P (fn_type));
> > > + gcc_assert (TREE_CODE (arg_types) == TREE_VEC);
> > > +
> > > + /* Access check is required to determine if the given is invocable. */
> > > + deferring_access_check_sentinel acs (dk_no_deferred);
> > > +
> > > + /* INVOKE is an unevaluated context. */
> > > + cp_unevaluated cp_uneval_guard;
> > > +
> > > + bool is_ptrdatamem;
> > > + bool is_ptrmemfunc;
> > > + if (TREE_CODE (fn_type) == REFERENCE_TYPE)
> > > + {
> > > + tree deref_fn_type = TREE_TYPE (fn_type);
> > > + is_ptrdatamem = TYPE_PTRDATAMEM_P (deref_fn_type);
> > > + is_ptrmemfunc = TYPE_PTRMEMFUNC_P (deref_fn_type);
> > > +
> > > + /* Dereference fn_type if it is a pointer to member. */
> > > + if (is_ptrdatamem || is_ptrmemfunc)
> > > + fn_type = deref_fn_type;
> > > + }
> > > + else
> > > + {
> > > + is_ptrdatamem = TYPE_PTRDATAMEM_P (fn_type);
> > > + is_ptrmemfunc = TYPE_PTRMEMFUNC_P (fn_type);
> > > + }
> > > +
> > > + if (is_ptrdatamem && TREE_VEC_LENGTH (arg_types) != 1)
> > > + /* Only a pointer to data member with one argument is invocable. */
> >
> > Just one note, if/when build_invoke gets a caller that passes tf_error
> > (for e.g. elaborating why is_invocable is false, or why invoke_result
> > is ill-formed) these error_mark_node code paths will need to issue
> > diagnostics b.
>
> Which function should we use for diagnostics - error, error_at, or
> something else? If we opt for error_at, which location information do
> we want to use?
>
Never mind, I can follow your finish_type_pack_element implementation :)
> >
> > > + return error_mark_node;
> > > +
> > > + if (is_ptrmemfunc && TREE_VEC_LENGTH (arg_types) == 0)
> > > + /* A pointer to member function with no arguments is not invocable. */
> > > + return error_mark_node;
> > > +
> > > + /* Construct an expression of a pointer to member. */
> > > + tree ptrmem_expr;
> > > + if (is_ptrdatamem || is_ptrmemfunc)
> > > + {
> > > + tree datum_type = TREE_VEC_ELT (arg_types, 0);
> > > +
> > > + /* datum must be a class type or a reference/pointer to a class type. */
> > > + if (TYPE_REF_P (datum_type) || POINTER_TYPE_P (datum_type))
> > > + {
> > > + if (!CLASS_TYPE_P (TREE_TYPE (datum_type)))
> > > + return error_mark_node;
> > > + }
> > > + else if (!CLASS_TYPE_P (datum_type))
> > > + return error_mark_node;
> > > +
> > > + bool is_refwrap = false;
> > > + if (CLASS_TYPE_P (datum_type))
> > > + {
> > > + /* 1.2 & 1.5: Handle std::reference_wrapper. */
> > > + tree datum_decl = TYPE_NAME (TYPE_MAIN_VARIANT (datum_type));
> > > + if (decl_in_std_namespace_p (datum_decl))
> > > + {
> > > + const_tree name = DECL_NAME (datum_decl);
> > > + if (name && (id_equal (name, "reference_wrapper")))
> > > + {
> > > + /* Retrieve T from std::reference_wrapper<T>,
> > > + i.e., decltype(datum.get()). */
> > > + datum_type = TREE_VEC_ELT (TYPE_TI_ARGS (datum_type), 0);
> > > + is_refwrap = true;
> > > + }
> > > + }
> > > + }
> > > +
> > > + tree datum_expr = build_trait_object (datum_type);
> > > + tree fn_expr = build_trait_object (fn_type);
> > > + ptrmem_expr = build_m_component_ref (datum_expr, fn_expr, complain);
> > > +
> > > + if (error_operand_p (ptrmem_expr) && !is_refwrap)
> > > + {
> > > + tree ptrmem_class_type = TYPE_PTRMEM_CLASS_TYPE (fn_type);
> > > + const bool ptrmem_is_base_of_datum =
> > > + (NON_UNION_CLASS_TYPE_P (ptrmem_class_type)
> > > + && NON_UNION_CLASS_TYPE_P (datum_type)
> > > + && (same_type_ignoring_top_level_qualifiers_p (ptrmem_class_type,
> > > + datum_type)
> > > + || DERIVED_FROM_P (ptrmem_class_type, datum_type)));
> > > +
> > > + if (!ptrmem_is_base_of_datum)
> > > + {
> > > + /* 1.3 & 1.6: Try to dereference datum_expr. */
> > > + datum_expr = build_x_indirect_ref (UNKNOWN_LOCATION, datum_expr,
> > > + RO_UNARY_STAR, NULL_TREE,
> > > + complain);
> > > + /* Rebuild ptrmem_expr. */
> > > + ptrmem_expr = build_m_component_ref (datum_expr, fn_expr,
> > > + complain);
> > > + }
> > > + }
> > > + /* 1.1 & 1.4: Otherwise. */
> > > +
> > > + if (error_operand_p (ptrmem_expr))
> > > + return error_mark_node;
> > > +
> > > + if (is_ptrdatamem)
> > > + return ptrmem_expr;
> > > + }
> > > +
> > > + /* Construct expressions for arguments to INVOKE. For a pointer to member
> > > + function, the first argument, which is the object, is not arguments to
> > > + the function. */
> > > + releasing_vec args;
> > > + for (int i = is_ptrmemfunc ? 1 : 0; i < TREE_VEC_LENGTH (arg_types); ++i)
> > > + {
> > > + tree arg_type = TREE_VEC_ELT (arg_types, i);
> > > + tree arg = build_trait_object (arg_type);
> > > + vec_safe_push (args, arg);
> > > + }
> > > +
> > > + tree invoke_expr;
> > > + if (is_ptrmemfunc)
> > > + invoke_expr = build_offset_ref_call_from_tree (ptrmem_expr, &args,
> > > + complain);
> > > + else /* 1.7. */
> > > + invoke_expr = finish_call_expr (build_trait_object (fn_type), &args, false,
> > > + false, complain);
> > > + return invoke_expr;
> > > +}
> > > +
> > > /* Determine which function will be called when looking up NAME in TYPE,
> > > called with a single ARGTYPE argument, or no argument if ARGTYPE is
> > > null. FLAGS and COMPLAIN are as for build_new_method_call.
> > > diff --git a/gcc/cp/semantics.cc b/gcc/cp/semantics.cc
> > > index 7242db75248..149c0631d62 100644
> > > --- a/gcc/cp/semantics.cc
> > > +++ b/gcc/cp/semantics.cc
> > > @@ -12467,6 +12467,9 @@ trait_expr_value (cp_trait_kind kind, tree type1, tree type2)
> > > case CPTK_IS_FUNCTION:
> > > return type_code1 == FUNCTION_TYPE;
> > >
> > > + case CPTK_IS_INVOCABLE:
> > > + return !error_operand_p (build_invoke (type1, type2, tf_none));
> > > +
> > > case CPTK_IS_LAYOUT_COMPATIBLE:
> > > return layout_compatible_type_p (type1, type2);
> > >
> > > @@ -12682,6 +12685,7 @@ finish_trait_expr (location_t loc, cp_trait_kind kind, tree type1, tree type2)
> > > break;
> > >
> > > case CPTK_IS_CONVERTIBLE:
> > > + case CPTK_IS_INVOCABLE:
> > > case CPTK_IS_NOTHROW_ASSIGNABLE:
> > > case CPTK_IS_NOTHROW_CONSTRUCTIBLE:
> > > case CPTK_IS_NOTHROW_CONVERTIBLE:
> > > diff --git a/gcc/testsuite/g++.dg/ext/has-builtin-1.C b/gcc/testsuite/g++.dg/ext/has-builtin-1.C
> > > index 7f7b27f7aa7..d2a7ebdf25c 100644
> > > --- a/gcc/testsuite/g++.dg/ext/has-builtin-1.C
> > > +++ b/gcc/testsuite/g++.dg/ext/has-builtin-1.C
> > > @@ -104,6 +104,9 @@
> > > #if !__has_builtin (__is_function)
> > > # error "__has_builtin (__is_function) failed"
> > > #endif
> > > +#if !__has_builtin (__is_invocable)
> > > +# error "__has_builtin (__is_invocable) failed"
> > > +#endif
> > > #if !__has_builtin (__is_layout_compatible)
> > > # error "__has_builtin (__is_layout_compatible) failed"
> > > #endif
> > > diff --git a/gcc/testsuite/g++.dg/ext/is_invocable1.C b/gcc/testsuite/g++.dg/ext/is_invocable1.C
> > > new file mode 100644
> > > index 00000000000..d21ae1d1958
> > > --- /dev/null
> > > +++ b/gcc/testsuite/g++.dg/ext/is_invocable1.C
> > > @@ -0,0 +1,349 @@
> > > +// { dg-do compile { target c++11 } }
> > > +
> > > +#define SA(X) static_assert((X),#X)
> > > +
> > > +using func_type_v0 = void(*)();
> > > +
> > > +SA( __is_invocable( func_type_v0 ) );
> > > +SA( ! __is_invocable( func_type_v0, int ) );
> > > +
> > > +using func_type_i0 = int(*)();
> > > +
> > > +SA( __is_invocable( func_type_i0 ) );
> > > +SA( ! __is_invocable( func_type_i0, int ) );
> > > +
> > > +using func_type_l0 = int&(*)();
> > > +
> > > +SA( __is_invocable( func_type_l0 ) );
> > > +SA( ! __is_invocable( func_type_l0(int) ) );
> > > +
> > > +using func_type_ii = int(*)(int);
> > > +
> > > +SA( ! __is_invocable( func_type_ii ) );
> > > +SA( __is_invocable( func_type_ii, int ) );
> > > +
> > > +using func_type_il = int(*)(int&);
> > > +
> > > +SA( ! __is_invocable( func_type_il ) );
> > > +SA( ! __is_invocable( func_type_il, int ) );
> > > +SA( __is_invocable( func_type_il, int& ) );
> > > +
> > > +using func_type_ir = int(*)(int&&);
> > > +
> > > +SA( ! __is_invocable( func_type_ir ) );
> > > +SA( ! __is_invocable( func_type_ir, int& ) );
> > > +SA( __is_invocable( func_type_ir, int ) );
> > > +SA( __is_invocable( func_type_ir, int&& ) );
> > > +
> > > +struct A { };
> > > +
> > > +using mem_type_i = int A::*;
> > > +
> > > +SA( ! __is_invocable( mem_type_i ) );
> > > +SA( ! __is_invocable( mem_type_i, int ) );
> > > +SA( ! __is_invocable( mem_type_i, int* ) );
> > > +SA( ! __is_invocable( mem_type_i, int& ) );
> > > +SA( ! __is_invocable( mem_type_i, int&& ) );
> > > +SA( __is_invocable( mem_type_i, A ) );
> > > +SA( __is_invocable( mem_type_i, A* ) );
> > > +SA( __is_invocable( mem_type_i, A& ) );
> > > +SA( __is_invocable( mem_type_i, A&& ) );
> > > +SA( __is_invocable( mem_type_i, const A& ) );
> > > +SA( ! __is_invocable( mem_type_i, A&, int ) );
> > > +
> > > +using memfun_type_i = int (A::*)();
> > > +
> > > +SA( ! __is_invocable( memfun_type_i ) );
> > > +SA( ! __is_invocable( memfun_type_i, int ) );
> > > +SA( ! __is_invocable( memfun_type_i, int* ) );
> > > +SA( ! __is_invocable( memfun_type_i, int& ) );
> > > +SA( ! __is_invocable( memfun_type_i, int&& ) );
> > > +SA( __is_invocable( memfun_type_i, A ) );
> > > +SA( __is_invocable( memfun_type_i, A* ) );
> > > +SA( __is_invocable( memfun_type_i, A& ) );
> > > +SA( __is_invocable( memfun_type_i, A&& ) );
> > > +SA( ! __is_invocable( memfun_type_i, const A& ) );
> > > +SA( ! __is_invocable( memfun_type_i, A&, int ) );
> > > +
> > > +using memfun_type_ic = int (A::*)() const;
> > > +
> > > +SA( ! __is_invocable( memfun_type_ic ) );
> > > +SA( ! __is_invocable( memfun_type_ic, int ) );
> > > +SA( ! __is_invocable( memfun_type_ic, int& ) );
> > > +SA( __is_invocable( memfun_type_ic, A& ) );
> > > +SA( __is_invocable( memfun_type_ic, A* ) );
> > > +SA( ! __is_invocable( memfun_type_ic, A&, int ) );
> > > +SA( ! __is_invocable( memfun_type_ic, A*, int& ) );
> > > +SA( __is_invocable( memfun_type_ic, const A& ) );
> > > +SA( __is_invocable( memfun_type_ic, const A* ) );
> > > +SA( ! __is_invocable( memfun_type_ic, const A&, int& ) );
> > > +SA( ! __is_invocable( memfun_type_ic, const A*, int ) );
> > > +
> > > +using memfun_type_iic = int& (A::*)(int&) const;
> > > +
> > > +SA( ! __is_invocable( memfun_type_iic ) );
> > > +SA( ! __is_invocable( memfun_type_iic, int ) );
> > > +SA( ! __is_invocable( memfun_type_iic, int& ) );
> > > +SA( ! __is_invocable( memfun_type_iic, A&, int ) );
> > > +SA( __is_invocable( memfun_type_iic, A&, int& ) );
> > > +SA( ! __is_invocable( memfun_type_iic, A*, int ) );
> > > +SA( __is_invocable( memfun_type_iic, A*, int& ) );
> > > +SA( ! __is_invocable( memfun_type_iic, const A&, int ) );
> > > +SA( ! __is_invocable( memfun_type_iic, const A&, int&, int ) );
> > > +SA( __is_invocable( memfun_type_iic, const A&, int& ) );
> > > +SA( __is_invocable( memfun_type_iic, const A*, int& ) );
> > > +
> > > +struct B {
> > > + int& operator()();
> > > + long& operator()() const;
> > > + bool& operator()(int);
> > > +private:
> > > + void operator()(int, int);
> > > +};
> > > +using CB = const B;
> > > +
> > > +SA( __is_invocable( B ) );
> > > +SA( __is_invocable( B& ) );
> > > +SA( __is_invocable( B&& ) );
> > > +SA( ! __is_invocable( B* ) );
> > > +SA( __is_invocable( CB ) );
> > > +SA( __is_invocable( CB& ) );
> > > +SA( ! __is_invocable( CB* ) );
> > > +
> > > +SA( __is_invocable( B, int ) );
> > > +SA( __is_invocable( B&, int ) );
> > > +SA( __is_invocable( B&&, int ) );
> > > +SA( ! __is_invocable( B*, int ) );
> > > +SA( ! __is_invocable( CB, int ) );
> > > +SA( ! __is_invocable( CB&, int ) );
> > > +SA( ! __is_invocable( CB*, int ) );
> > > +
> > > +SA( ! __is_invocable( B, int, int ) );
> > > +SA( ! __is_invocable( B&, int, int ) );
> > > +SA( ! __is_invocable( B&&, int, int ) );
> > > +SA( ! __is_invocable( B*, int, int ) );
> > > +SA( ! __is_invocable( CB, int, int ) );
> > > +SA( ! __is_invocable( CB&, int, int ) );
> > > +SA( ! __is_invocable( CB*, int, int ) );
> > > +
> > > +struct C : B { int& operator()() = delete; };
> > > +using CC = const C;
> > > +
> > > +SA( ! __is_invocable( C ) );
> > > +SA( ! __is_invocable( C& ) );
> > > +SA( ! __is_invocable( C&& ) );
> > > +SA( ! __is_invocable( C* ) );
> > > +SA( ! __is_invocable( CC ) );
> > > +SA( ! __is_invocable( CC& ) );
> > > +SA( ! __is_invocable( CC* ) );
> > > +
> > > +struct D { B operator*(); };
> > > +using CD = const D;
> > > +
> > > +SA( ! __is_invocable( D ) );
> > > +
> > > +struct E { void v(); };
> > > +using CE = const E;
> > > +
> > > +SA( ! __is_invocable( E ) );
> > > +SA( ! __is_invocable( void (E::*)() ) );
> > > +SA( __is_invocable( void (E::*)(), E ) );
> > > +SA( __is_invocable( void (E::*)(), E* ) );
> > > +SA( ! __is_invocable( void (E::*)(), CE ) );
> > > +
> > > +struct F : E {};
> > > +using CF = const F;
> > > +
> > > +SA( ! __is_invocable( F ) );
> > > +SA( __is_invocable( void (E::*)(), F ) );
> > > +SA( __is_invocable( void (E::*)(), F* ) );
> > > +SA( ! __is_invocable( void (E::*)(), CF ) );
> > > +
> > > +struct G { E operator*(); };
> > > +using CG = const G;
> > > +
> > > +SA( ! __is_invocable( G ) );
> > > +SA( __is_invocable( void (E::*)(), G ) );
> > > +SA( ! __is_invocable( void (E::*)(), G* ) );
> > > +SA( ! __is_invocable( void (E::*)(), CG ) );
> > > +
> > > +struct H { E& operator*(); };
> > > +using CH = const H;
> > > +
> > > +SA( ! __is_invocable( H ) );
> > > +SA( __is_invocable( void (E::*)(), H ) );
> > > +SA( ! __is_invocable( void (E::*)(), H* ) );
> > > +SA( ! __is_invocable( void (E::*)(), CH ) );
> > > +
> > > +struct I { E&& operator*(); };
> > > +using CI = const I;
> > > +
> > > +SA( ! __is_invocable( I ) );
> > > +SA( __is_invocable( void (E::*)(), I ) );
> > > +SA( ! __is_invocable( void (E::*)(), I* ) );
> > > +SA( ! __is_invocable( void (E::*)(), CI ) );
> > > +
> > > +struct K { E* operator*(); };
> > > +using CK = const K;
> > > +
> > > +SA( ! __is_invocable( K ) );
> > > +SA( ! __is_invocable( void (E::*)(), K ) );
> > > +SA( ! __is_invocable( void (E::*)(), K* ) );
> > > +SA( ! __is_invocable( void (E::*)(), CK ) );
> > > +
> > > +struct L { CE operator*(); };
> > > +using CL = const L;
> > > +
> > > +SA( ! __is_invocable( L ) );
> > > +SA( ! __is_invocable( void (E::*)(), L ) );
> > > +SA( ! __is_invocable( void (E::*)(), L* ) );
> > > +SA( ! __is_invocable( void (E::*)(), CL ) );
> > > +
> > > +struct M {
> > > + int i;
> > > +private:
> > > + long l;
> > > +};
> > > +using CM = const M;
> > > +
> > > +SA( ! __is_invocable( M ) );
> > > +SA( ! __is_invocable( M& ) );
> > > +SA( ! __is_invocable( M&& ) );
> > > +SA( ! __is_invocable( M* ) );
> > > +SA( ! __is_invocable( CM ) );
> > > +SA( ! __is_invocable( CM& ) );
> > > +SA( ! __is_invocable( CM* ) );
> > > +
> > > +SA( ! __is_invocable( int M::* ) );
> > > +SA( __is_invocable( int M::*, M ) );
> > > +SA( __is_invocable( int M::*, M& ) );
> > > +SA( __is_invocable( int M::*, M&& ) );
> > > +SA( __is_invocable( int M::*, M* ) );
> > > +SA( __is_invocable( int M::*, CM ) );
> > > +SA( __is_invocable( int M::*, CM& ) );
> > > +SA( __is_invocable( int M::*, CM* ) );
> > > +SA( ! __is_invocable( int M::*, int ) );
> > > +
> > > +SA( ! __is_invocable( int CM::* ) );
> > > +SA( __is_invocable( int CM::*, M ) );
> > > +SA( __is_invocable( int CM::*, M& ) );
> > > +SA( __is_invocable( int CM::*, M&& ) );
> > > +SA( __is_invocable( int CM::*, M* ) );
> > > +SA( __is_invocable( int CM::*, CM ) );
> > > +SA( __is_invocable( int CM::*, CM& ) );
> > > +SA( __is_invocable( int CM::*, CM* ) );
> > > +SA( ! __is_invocable( int CM::*, int ) );
> > > +
> > > +SA( ! __is_invocable( long M::* ) );
> > > +SA( __is_invocable( long M::*, M ) );
> > > +SA( __is_invocable( long M::*, M& ) );
> > > +SA( __is_invocable( long M::*, M&& ) );
> > > +SA( __is_invocable( long M::*, M* ) );
> > > +SA( __is_invocable( long M::*, CM ) );
> > > +SA( __is_invocable( long M::*, CM& ) );
> > > +SA( __is_invocable( long M::*, CM* ) );
> > > +SA( ! __is_invocable( long M::*, long ) );
> > > +
> > > +SA( ! __is_invocable( long CM::* ) );
> > > +SA( __is_invocable( long CM::*, M ) );
> > > +SA( __is_invocable( long CM::*, M& ) );
> > > +SA( __is_invocable( long CM::*, M&& ) );
> > > +SA( __is_invocable( long CM::*, M* ) );
> > > +SA( __is_invocable( long CM::*, CM ) );
> > > +SA( __is_invocable( long CM::*, CM& ) );
> > > +SA( __is_invocable( long CM::*, CM* ) );
> > > +SA( ! __is_invocable( long CM::*, long ) );
> > > +
> > > +SA( ! __is_invocable( short M::* ) );
> > > +SA( __is_invocable( short M::*, M ) );
> > > +SA( __is_invocable( short M::*, M& ) );
> > > +SA( __is_invocable( short M::*, M&& ) );
> > > +SA( __is_invocable( short M::*, M* ) );
> > > +SA( __is_invocable( short M::*, CM ) );
> > > +SA( __is_invocable( short M::*, CM& ) );
> > > +SA( __is_invocable( short M::*, CM* ) );
> > > +SA( ! __is_invocable( short M::*, short ) );
> > > +
> > > +SA( ! __is_invocable( short CM::* ) );
> > > +SA( __is_invocable( short CM::*, M ) );
> > > +SA( __is_invocable( short CM::*, M& ) );
> > > +SA( __is_invocable( short CM::*, M&& ) );
> > > +SA( __is_invocable( short CM::*, M* ) );
> > > +SA( __is_invocable( short CM::*, CM ) );
> > > +SA( __is_invocable( short CM::*, CM& ) );
> > > +SA( __is_invocable( short CM::*, CM* ) );
> > > +SA( ! __is_invocable( short CM::*, short ) );
> > > +
> > > +struct N { M operator*(); };
> > > +SA( __is_invocable( int M::*, N ) );
> > > +SA( ! __is_invocable( int M::*, N* ) );
> > > +
> > > +struct O { M& operator*(); };
> > > +SA( __is_invocable( int M::*, O ) );
> > > +SA( ! __is_invocable( int M::*, O* ) );
> > > +
> > > +struct P { M&& operator*(); };
> > > +SA( __is_invocable( int M::*, P ) );
> > > +SA( ! __is_invocable( int M::*, P* ) );
> > > +
> > > +struct Q { M* operator*(); };
> > > +SA( ! __is_invocable( int M::*, Q ) );
> > > +SA( ! __is_invocable( int M::*, Q* ) );
> > > +
> > > +struct R { void operator()(int = 0); };
> > > +
> > > +SA( __is_invocable( R ) );
> > > +SA( __is_invocable( R, int ) );
> > > +SA( ! __is_invocable( R, int, int ) );
> > > +
> > > +struct S { void operator()(int, ...); };
> > > +
> > > +SA( ! __is_invocable( S ) );
> > > +SA( __is_invocable( S, int ) );
> > > +SA( __is_invocable( S, int, int ) );
> > > +SA( __is_invocable( S, int, int, int ) );
> > > +
> > > +void fn1() {}
> > > +
> > > +SA( __is_invocable( decltype(fn1) ) );
> > > +
> > > +void fn2(int arr[10]);
> > > +
> > > +SA( __is_invocable( decltype(fn2), int[10] ) );
> > > +SA( __is_invocable( decltype(fn2), int(&)[10] ) );
> > > +SA( __is_invocable( decltype(fn2), int(&&)[10] ) );
> > > +SA( ! __is_invocable( decltype(fn2), int(*)[10] ) );
> > > +SA( ! __is_invocable( decltype(fn2), int(*&)[10] ) );
> > > +SA( ! __is_invocable( decltype(fn2), int(*&&)[10] ) );
> > > +SA( __is_invocable( decltype(fn2), int[] ) );
> > > +
> > > +auto lambda = []() {};
> > > +
> > > +SA( __is_invocable( decltype(lambda) ) );
> > > +
> > > +template <typename Func, typename... Args>
> > > +struct can_invoke {
> > > + static constexpr bool value = __is_invocable( Func, Args... );
> > > +};
> > > +
> > > +SA( can_invoke<decltype(lambda)>::value );
> > > +
> > > +struct T {
> > > + void func() const {}
> > > + int data;
> > > +};
> > > +
> > > +SA( __is_invocable( decltype(&T::func)&, T& ) );
> > > +SA( __is_invocable( decltype(&T::data)&, T& ) );
> > > +
> > > +struct U { };
> > > +struct V : U { U& operator*() = delete; };
> > > +SA( __is_invocable( int U::*, V ) );
> > > +
> > > +struct W : private U { U& operator*(); };
> > > +SA( ! __is_invocable( int U::*, W ) );
> > > +
> > > +struct X { int m; };
> > > +struct Y { X& operator*(); };
> > > +struct Z : Y { };
> > > +SA( __is_invocable(int X::*, Z) );
> > > diff --git a/gcc/testsuite/g++.dg/ext/is_invocable2.C b/gcc/testsuite/g++.dg/ext/is_invocable2.C
> > > new file mode 100644
> > > index 00000000000..a68aefd3e13
> > > --- /dev/null
> > > +++ b/gcc/testsuite/g++.dg/ext/is_invocable2.C
> > > @@ -0,0 +1,139 @@
> > > +// { dg-do compile { target c++11 } }
> > > +// __is_invocable should handle std::reference_wrapper correctly.
> > > +
> > > +#include <functional>
> > > +
> > > +#define SA(X) static_assert((X),#X)
> > > +
> > > +using std::reference_wrapper;
> > > +
> > > +using func_type_v0 = void(*)();
> > > +
> > > +SA( __is_invocable( reference_wrapper<func_type_v0> ) );
> > > +SA( ! __is_invocable( reference_wrapper<func_type_v0>, int ) );
> > > +
> > > +using func_type_i0 = int(*)();
> > > +
> > > +SA( __is_invocable( reference_wrapper<func_type_i0> ) );
> > > +SA( ! __is_invocable( reference_wrapper<func_type_i0>, int ) );
> > > +
> > > +using func_type_l0 = int&(*)();
> > > +
> > > +SA( __is_invocable( reference_wrapper<func_type_l0> ) );
> > > +SA( ! __is_invocable( reference_wrapper<func_type_l0(int)> ) );
> > > +
> > > +using func_type_ii = int(*)(int);
> > > +
> > > +SA( ! __is_invocable( reference_wrapper<func_type_ii> ) );
> > > +SA( __is_invocable( reference_wrapper<func_type_ii>, int ) );
> > > +
> > > +using func_type_il = int(*)(int&);
> > > +
> > > +SA( ! __is_invocable( reference_wrapper<func_type_il> ) );
> > > +SA( ! __is_invocable( reference_wrapper<func_type_il>, int ) );
> > > +SA( __is_invocable( reference_wrapper<func_type_il>, int& ) );
> > > +
> > > +using func_type_ir = int(*)(int&&);
> > > +
> > > +SA( ! __is_invocable( reference_wrapper<func_type_ir> ) );
> > > +SA( ! __is_invocable( reference_wrapper<func_type_ir>, int& ) );
> > > +SA( __is_invocable( reference_wrapper<func_type_ir>, int ) );
> > > +SA( __is_invocable( reference_wrapper<func_type_ir>, int&& ) );
> > > +
> > > +struct A { };
> > > +
> > > +using mem_type_i = int A::*;
> > > +
> > > +SA( ! __is_invocable( reference_wrapper<mem_type_i> ) );
> > > +SA( ! __is_invocable( reference_wrapper<mem_type_i>, int ) );
> > > +SA( ! __is_invocable( reference_wrapper<mem_type_i>, int* ) );
> > > +SA( ! __is_invocable( reference_wrapper<mem_type_i>, int& ) );
> > > +SA( ! __is_invocable( reference_wrapper<mem_type_i>, int&& ) );
> > > +SA( __is_invocable( reference_wrapper<mem_type_i>, A ) );
> > > +SA( __is_invocable( reference_wrapper<mem_type_i>, A* ) );
> > > +SA( __is_invocable( reference_wrapper<mem_type_i>, A& ) );
> > > +SA( __is_invocable( reference_wrapper<mem_type_i>, A&& ) );
> > > +
> > > +using memfun_type_i = int (A::*)();
> > > +
> > > +SA( ! __is_invocable( reference_wrapper<memfun_type_i> ) );
> > > +SA( ! __is_invocable( reference_wrapper<memfun_type_i>, int ) );
> > > +SA( ! __is_invocable( reference_wrapper<memfun_type_i>, int* ) );
> > > +SA( ! __is_invocable( reference_wrapper<memfun_type_i>, int& ) );
> > > +SA( ! __is_invocable( reference_wrapper<memfun_type_i>, int&& ) );
> > > +SA( __is_invocable( reference_wrapper<memfun_type_i>, A ) );
> > > +SA( __is_invocable( reference_wrapper<memfun_type_i>, A* ) );
> > > +SA( __is_invocable( reference_wrapper<memfun_type_i>, A& ) );
> > > +SA( __is_invocable( reference_wrapper<memfun_type_i>, A&& ) );
> > > +SA( ! __is_invocable( reference_wrapper<memfun_type_i>, const A& ) );
> > > +SA( ! __is_invocable( reference_wrapper<memfun_type_i>, A&, int ) );
> > > +
> > > +using memfun_type_ic = int (A::*)() const;
> > > +
> > > +SA( ! __is_invocable( reference_wrapper<memfun_type_ic> ) );
> > > +SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, int ) );
> > > +SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, int& ) );
> > > +SA( __is_invocable( reference_wrapper<memfun_type_ic>, A& ) );
> > > +SA( __is_invocable( reference_wrapper<memfun_type_ic>, A* ) );
> > > +SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, A&, int ) );
> > > +SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, A*, int& ) );
> > > +SA( __is_invocable( reference_wrapper<memfun_type_ic>, const A& ) );
> > > +SA( __is_invocable( reference_wrapper<memfun_type_ic>, const A* ) );
> > > +SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, const A&, int& ) );
> > > +SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, const A*, int ) );
> > > +
> > > +using memfun_type_iic = int& (A::*)(int&) const;
> > > +
> > > +SA( ! __is_invocable( reference_wrapper<memfun_type_iic> ) );
> > > +SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, int ) );
> > > +SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, int& ) );
> > > +SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, A&, int ) );
> > > +SA( __is_invocable( reference_wrapper<memfun_type_iic>, A&, int& ) );
> > > +SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, A*, int ) );
> > > +SA( __is_invocable( reference_wrapper<memfun_type_iic>, A*, int& ) );
> > > +SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, const A&, int ) );
> > > +SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, const A&, int&, int ) );
> > > +SA( __is_invocable( reference_wrapper<memfun_type_iic>, const A&, int& ) );
> > > +SA( __is_invocable( reference_wrapper<memfun_type_iic>, const A*, int& ) );
> > > +
> > > +struct B {
> > > + int& operator()();
> > > + long& operator()() const;
> > > + bool& operator()(int);
> > > +private:
> > > + void operator()(int, int);
> > > +};
> > > +using CB = const B;
> > > +
> > > +SA( __is_invocable( reference_wrapper<B> ) );
> > > +SA( __is_invocable( reference_wrapper<B>& ) );
> > > +SA( __is_invocable( reference_wrapper<B>&& ) );
> > > +SA( __is_invocable( reference_wrapper<CB> ) );
> > > +SA( __is_invocable( reference_wrapper<CB>& ) );
> > > +SA( __is_invocable( reference_wrapper<B>, int ) );
> > > +SA( ! __is_invocable( reference_wrapper<B>&, int, int ) );
> > > +
> > > +struct C : B { int& operator()() = delete; };
> > > +using CC = const C;
> > > +
> > > +SA( ! __is_invocable( reference_wrapper<C> ) );
> > > +SA( ! __is_invocable( reference_wrapper<C>& ) );
> > > +SA( ! __is_invocable( reference_wrapper<C>&& ) );
> > > +SA( ! __is_invocable( reference_wrapper<CC> ) );
> > > +SA( ! __is_invocable( reference_wrapper<CC>& ) );
> > > +
> > > +struct D { B operator*(); };
> > > +using CD = const D;
> > > +
> > > +SA( ! __is_invocable( reference_wrapper<D> ) );
> > > +SA( ! __is_invocable( reference_wrapper<D>& ) );
> > > +SA( ! __is_invocable( reference_wrapper<D>&& ) );
> > > +SA( ! __is_invocable( reference_wrapper<D>* ) );
> > > +SA( ! __is_invocable( reference_wrapper<D*> ) );
> > > +SA( ! __is_invocable( reference_wrapper<D*>* ) );
> > > +
> > > +std::function<void()> fn = []() {};
> > > +auto refwrap = std::ref(fn);
> > > +
> > > +SA( __is_invocable( decltype(fn) ) );
> > > +SA( __is_invocable( decltype(refwrap) ) );
> > > diff --git a/gcc/testsuite/g++.dg/ext/is_invocable3.C b/gcc/testsuite/g++.dg/ext/is_invocable3.C
> > > new file mode 100644
> > > index 00000000000..8699b0a53ca
> > > --- /dev/null
> > > +++ b/gcc/testsuite/g++.dg/ext/is_invocable3.C
> > > @@ -0,0 +1,51 @@
> > > +// { dg-do compile { target c++11 } }
> > > +// __is_invocable should handle incomplete class correctly.
> > > +
> > > +#define SA(X) static_assert((X),#X)
> > > +
> > > +struct Incomplete;
> > > +
> > > +SA( ! __is_invocable( Incomplete ) ); // { dg-error "incomplete type" }
> > > +SA( ! __is_invocable( Incomplete, int ) ); // { dg-error "incomplete type" }
> > > +
> > > +SA( ! __is_invocable( int, Incomplete, int ) ); // { dg-error "incomplete type" }
> > > +SA( ! __is_invocable( int, Incomplete ) ); // { dg-error "incomplete type" }
> > > +
> > > +SA( ! __is_invocable( Incomplete, Incomplete() ) ); // { dg-error "incomplete type" }
> > > +SA( ! __is_invocable( Incomplete, Incomplete(int), int ) ); // { dg-error "incomplete type" }
> > > +SA( ! __is_invocable( Incomplete, Incomplete(int, int), int, int ) ); // { dg-error "incomplete type" }
> > > +
> > > +SA( ! __is_invocable( Incomplete, Incomplete(), int, int ) ); // { dg-error "incomplete type" }
> > > +
> > > +SA( ! __is_invocable( int(Incomplete), Incomplete ) ); // { dg-error "incomplete type" }
> > > +SA( ! __is_invocable( int(int, Incomplete), int, Incomplete ) ); // { dg-error "incomplete type" }
> > > +SA( ! __is_invocable( int(int, Incomplete), Incomplete, int ) ); // { dg-error "incomplete type" }
> > > +
> > > +SA( __is_invocable( int(Incomplete&), Incomplete& ) ); // { dg-bogus "incomplete type" }
> > > +SA( __is_invocable( int(int, Incomplete&), int, Incomplete& ) ); // { dg-bogus "incomplete type" }
> > > +
> > > +SA( __is_invocable( int(Incomplete&&), Incomplete&& ) ); // { dg-bogus "incomplete type" }
> > > +SA( __is_invocable( int(int, Incomplete&&), int, Incomplete&& ) ); // { dg-bogus "incomplete type" }
> > > +
> > > +SA( __is_invocable( int(const Incomplete&&), const Incomplete&& ) ); // { dg-bogus "incomplete type" }
> > > +SA( __is_invocable( int(int, const Incomplete&&), int, const Incomplete&& ) ); // { dg-bogus "incomplete type" }
> > > +
> > > +SA( __is_invocable( int(const Incomplete&), const Incomplete& ) ); // { dg-bogus "incomplete type" }
> > > +SA( __is_invocable( int(int, const Incomplete&), int, const Incomplete& ) ); // { dg-bogus "incomplete type" }
> > > +
> > > +SA( __is_invocable( int(const Incomplete&), Incomplete& ) ); // { dg-bogus "incomplete type" }
> > > +SA( __is_invocable( int(int, const Incomplete&), int, Incomplete& ) ); // { dg-bogus "incomplete type" }
> > > +
> > > +SA( __is_invocable( int Incomplete::*, const Incomplete& ) ); // { dg-bogus "incomplete type" }
> > > +SA( ! __is_invocable( void (Incomplete::*)(long&), const Incomplete*, long& ) ); // { dg-bogus "incomplete type" }
> > > +SA( __is_invocable( void (Incomplete::*)(long&) const, Incomplete*, long& ) ); // { dg-bogus "incomplete type" }
> > > +
> > > +template <typename T>
> > > +struct Holder { T t; };
> > > +
> > > +SA( __is_invocable( int(Holder<Incomplete>&), Holder<Incomplete>& ) ); // { dg-bogus "incomplete type" }
> > > +
> > > +// Define Incomplete, which is now not incomplete.
> > > +struct Incomplete { void operator()(); };
> > > +
> > > +SA( __is_invocable( Incomplete ) ); // { dg-bogus "incomplete type" }
> > > diff --git a/gcc/testsuite/g++.dg/ext/is_invocable4.C b/gcc/testsuite/g++.dg/ext/is_invocable4.C
> > > new file mode 100644
> > > index 00000000000..d1efccf08f8
> > > --- /dev/null
> > > +++ b/gcc/testsuite/g++.dg/ext/is_invocable4.C
> > > @@ -0,0 +1,33 @@
> > > +// { dg-do compile { target c++11 } }
> > > +// Failed access check should be a substitution failure, not an error.
> > > +
> > > +#define SA(X) static_assert((X),#X)
> > > +
> > > +template<bool B>
> > > +struct bool_constant { static constexpr bool value = B; };
> > > +
> > > +template<typename _Fn, typename... _ArgTypes>
> > > +struct is_invocable
> > > +: public bool_constant<__is_invocable(_Fn, _ArgTypes...)>
> > > +{ };
> > > +
> > > +#if __cpp_variable_templates
> > > +template<typename _Fn, typename... _ArgTypes>
> > > +constexpr bool is_invocable_v = __is_invocable(_Fn, _ArgTypes...);
> > > +#endif
> > > +
> > > +class Private
> > > +{
> > > + void operator()() const
> > > + {
> > > + SA( ! is_invocable<Private>::value );
> > > +#if __cpp_variable_templates
> > > + SA( ! is_invocable_v<Private> );
> > > +#endif
> > > + }
> > > +};
> > > +
> > > +SA( ! is_invocable<Private>::value );
> > > +#if __cpp_variable_templates
> > > +SA( ! is_invocable_v<Private> );
> > > +#endif
> > > --
> > > 2.44.0
> > >
> > >
> >
@@ -3791,6 +3791,12 @@ diagnose_trait_expr (tree expr, tree args)
case CPTK_IS_FUNCTION:
inform (loc, " %qT is not a function", t1);
break;
+ case CPTK_IS_INVOCABLE:
+ if (!t2)
+ inform (loc, " %qT is not invocable", t1);
+ else
+ inform (loc, " %qT is not invocable by %qE", t1, t2);
+ break;
case CPTK_IS_LAYOUT_COMPATIBLE:
inform (loc, " %qT is not layout compatible with %qT", t1, t2);
break;
@@ -75,6 +75,7 @@ DEFTRAIT_EXPR (IS_EMPTY, "__is_empty", 1)
DEFTRAIT_EXPR (IS_ENUM, "__is_enum", 1)
DEFTRAIT_EXPR (IS_FINAL, "__is_final", 1)
DEFTRAIT_EXPR (IS_FUNCTION, "__is_function", 1)
+DEFTRAIT_EXPR (IS_INVOCABLE, "__is_invocable", -1)
DEFTRAIT_EXPR (IS_LAYOUT_COMPATIBLE, "__is_layout_compatible", 2)
DEFTRAIT_EXPR (IS_LITERAL_TYPE, "__is_literal_type", 1)
DEFTRAIT_EXPR (IS_MEMBER_FUNCTION_POINTER, "__is_member_function_pointer", 1)
@@ -7334,6 +7334,8 @@ extern tree get_copy_assign (tree);
extern tree get_default_ctor (tree);
extern tree get_dtor (tree, tsubst_flags_t);
extern tree build_stub_object (tree);
+extern tree build_invoke (tree, const_tree,
+ tsubst_flags_t);
extern tree strip_inheriting_ctors (tree);
extern tree inherited_ctor_binfo (tree);
extern bool base_ctor_omit_inherited_parms (tree);
@@ -1928,6 +1928,138 @@ build_trait_object (tree type)
return build_stub_object (type);
}
+/* [func.require] Build an expression of INVOKE(FN_TYPE, ARG_TYPES...). If the
+ given is not invocable, returns error_mark_node. */
+
+tree
+build_invoke (tree fn_type, const_tree arg_types, tsubst_flags_t complain)
+{
+ if (fn_type == error_mark_node || arg_types == error_mark_node)
+ return error_mark_node;
+
+ gcc_assert (TYPE_P (fn_type));
+ gcc_assert (TREE_CODE (arg_types) == TREE_VEC);
+
+ /* Access check is required to determine if the given is invocable. */
+ deferring_access_check_sentinel acs (dk_no_deferred);
+
+ /* INVOKE is an unevaluated context. */
+ cp_unevaluated cp_uneval_guard;
+
+ bool is_ptrdatamem;
+ bool is_ptrmemfunc;
+ if (TREE_CODE (fn_type) == REFERENCE_TYPE)
+ {
+ tree deref_fn_type = TREE_TYPE (fn_type);
+ is_ptrdatamem = TYPE_PTRDATAMEM_P (deref_fn_type);
+ is_ptrmemfunc = TYPE_PTRMEMFUNC_P (deref_fn_type);
+
+ /* Dereference fn_type if it is a pointer to member. */
+ if (is_ptrdatamem || is_ptrmemfunc)
+ fn_type = deref_fn_type;
+ }
+ else
+ {
+ is_ptrdatamem = TYPE_PTRDATAMEM_P (fn_type);
+ is_ptrmemfunc = TYPE_PTRMEMFUNC_P (fn_type);
+ }
+
+ if (is_ptrdatamem && TREE_VEC_LENGTH (arg_types) != 1)
+ /* Only a pointer to data member with one argument is invocable. */
+ return error_mark_node;
+
+ if (is_ptrmemfunc && TREE_VEC_LENGTH (arg_types) == 0)
+ /* A pointer to member function with no arguments is not invocable. */
+ return error_mark_node;
+
+ /* Construct an expression of a pointer to member. */
+ tree ptrmem_expr;
+ if (is_ptrdatamem || is_ptrmemfunc)
+ {
+ tree datum_type = TREE_VEC_ELT (arg_types, 0);
+
+ /* datum must be a class type or a reference/pointer to a class type. */
+ if (TYPE_REF_P (datum_type) || POINTER_TYPE_P (datum_type))
+ {
+ if (!CLASS_TYPE_P (TREE_TYPE (datum_type)))
+ return error_mark_node;
+ }
+ else if (!CLASS_TYPE_P (datum_type))
+ return error_mark_node;
+
+ bool is_refwrap = false;
+ if (CLASS_TYPE_P (datum_type))
+ {
+ /* 1.2 & 1.5: Handle std::reference_wrapper. */
+ tree datum_decl = TYPE_NAME (TYPE_MAIN_VARIANT (datum_type));
+ if (decl_in_std_namespace_p (datum_decl))
+ {
+ const_tree name = DECL_NAME (datum_decl);
+ if (name && (id_equal (name, "reference_wrapper")))
+ {
+ /* Retrieve T from std::reference_wrapper<T>,
+ i.e., decltype(datum.get()). */
+ datum_type = TREE_VEC_ELT (TYPE_TI_ARGS (datum_type), 0);
+ is_refwrap = true;
+ }
+ }
+ }
+
+ tree datum_expr = build_trait_object (datum_type);
+ tree fn_expr = build_trait_object (fn_type);
+ ptrmem_expr = build_m_component_ref (datum_expr, fn_expr, complain);
+
+ if (error_operand_p (ptrmem_expr) && !is_refwrap)
+ {
+ tree ptrmem_class_type = TYPE_PTRMEM_CLASS_TYPE (fn_type);
+ const bool ptrmem_is_base_of_datum =
+ (NON_UNION_CLASS_TYPE_P (ptrmem_class_type)
+ && NON_UNION_CLASS_TYPE_P (datum_type)
+ && (same_type_ignoring_top_level_qualifiers_p (ptrmem_class_type,
+ datum_type)
+ || DERIVED_FROM_P (ptrmem_class_type, datum_type)));
+
+ if (!ptrmem_is_base_of_datum)
+ {
+ /* 1.3 & 1.6: Try to dereference datum_expr. */
+ datum_expr = build_x_indirect_ref (UNKNOWN_LOCATION, datum_expr,
+ RO_UNARY_STAR, NULL_TREE,
+ complain);
+ /* Rebuild ptrmem_expr. */
+ ptrmem_expr = build_m_component_ref (datum_expr, fn_expr,
+ complain);
+ }
+ }
+ /* 1.1 & 1.4: Otherwise. */
+
+ if (error_operand_p (ptrmem_expr))
+ return error_mark_node;
+
+ if (is_ptrdatamem)
+ return ptrmem_expr;
+ }
+
+ /* Construct expressions for arguments to INVOKE. For a pointer to member
+ function, the first argument, which is the object, is not arguments to
+ the function. */
+ releasing_vec args;
+ for (int i = is_ptrmemfunc ? 1 : 0; i < TREE_VEC_LENGTH (arg_types); ++i)
+ {
+ tree arg_type = TREE_VEC_ELT (arg_types, i);
+ tree arg = build_trait_object (arg_type);
+ vec_safe_push (args, arg);
+ }
+
+ tree invoke_expr;
+ if (is_ptrmemfunc)
+ invoke_expr = build_offset_ref_call_from_tree (ptrmem_expr, &args,
+ complain);
+ else /* 1.7. */
+ invoke_expr = finish_call_expr (build_trait_object (fn_type), &args, false,
+ false, complain);
+ return invoke_expr;
+}
+
/* Determine which function will be called when looking up NAME in TYPE,
called with a single ARGTYPE argument, or no argument if ARGTYPE is
null. FLAGS and COMPLAIN are as for build_new_method_call.
@@ -12467,6 +12467,9 @@ trait_expr_value (cp_trait_kind kind, tree type1, tree type2)
case CPTK_IS_FUNCTION:
return type_code1 == FUNCTION_TYPE;
+ case CPTK_IS_INVOCABLE:
+ return !error_operand_p (build_invoke (type1, type2, tf_none));
+
case CPTK_IS_LAYOUT_COMPATIBLE:
return layout_compatible_type_p (type1, type2);
@@ -12682,6 +12685,7 @@ finish_trait_expr (location_t loc, cp_trait_kind kind, tree type1, tree type2)
break;
case CPTK_IS_CONVERTIBLE:
+ case CPTK_IS_INVOCABLE:
case CPTK_IS_NOTHROW_ASSIGNABLE:
case CPTK_IS_NOTHROW_CONSTRUCTIBLE:
case CPTK_IS_NOTHROW_CONVERTIBLE:
@@ -104,6 +104,9 @@
#if !__has_builtin (__is_function)
# error "__has_builtin (__is_function) failed"
#endif
+#if !__has_builtin (__is_invocable)
+# error "__has_builtin (__is_invocable) failed"
+#endif
#if !__has_builtin (__is_layout_compatible)
# error "__has_builtin (__is_layout_compatible) failed"
#endif
new file mode 100644
@@ -0,0 +1,349 @@
+// { dg-do compile { target c++11 } }
+
+#define SA(X) static_assert((X),#X)
+
+using func_type_v0 = void(*)();
+
+SA( __is_invocable( func_type_v0 ) );
+SA( ! __is_invocable( func_type_v0, int ) );
+
+using func_type_i0 = int(*)();
+
+SA( __is_invocable( func_type_i0 ) );
+SA( ! __is_invocable( func_type_i0, int ) );
+
+using func_type_l0 = int&(*)();
+
+SA( __is_invocable( func_type_l0 ) );
+SA( ! __is_invocable( func_type_l0(int) ) );
+
+using func_type_ii = int(*)(int);
+
+SA( ! __is_invocable( func_type_ii ) );
+SA( __is_invocable( func_type_ii, int ) );
+
+using func_type_il = int(*)(int&);
+
+SA( ! __is_invocable( func_type_il ) );
+SA( ! __is_invocable( func_type_il, int ) );
+SA( __is_invocable( func_type_il, int& ) );
+
+using func_type_ir = int(*)(int&&);
+
+SA( ! __is_invocable( func_type_ir ) );
+SA( ! __is_invocable( func_type_ir, int& ) );
+SA( __is_invocable( func_type_ir, int ) );
+SA( __is_invocable( func_type_ir, int&& ) );
+
+struct A { };
+
+using mem_type_i = int A::*;
+
+SA( ! __is_invocable( mem_type_i ) );
+SA( ! __is_invocable( mem_type_i, int ) );
+SA( ! __is_invocable( mem_type_i, int* ) );
+SA( ! __is_invocable( mem_type_i, int& ) );
+SA( ! __is_invocable( mem_type_i, int&& ) );
+SA( __is_invocable( mem_type_i, A ) );
+SA( __is_invocable( mem_type_i, A* ) );
+SA( __is_invocable( mem_type_i, A& ) );
+SA( __is_invocable( mem_type_i, A&& ) );
+SA( __is_invocable( mem_type_i, const A& ) );
+SA( ! __is_invocable( mem_type_i, A&, int ) );
+
+using memfun_type_i = int (A::*)();
+
+SA( ! __is_invocable( memfun_type_i ) );
+SA( ! __is_invocable( memfun_type_i, int ) );
+SA( ! __is_invocable( memfun_type_i, int* ) );
+SA( ! __is_invocable( memfun_type_i, int& ) );
+SA( ! __is_invocable( memfun_type_i, int&& ) );
+SA( __is_invocable( memfun_type_i, A ) );
+SA( __is_invocable( memfun_type_i, A* ) );
+SA( __is_invocable( memfun_type_i, A& ) );
+SA( __is_invocable( memfun_type_i, A&& ) );
+SA( ! __is_invocable( memfun_type_i, const A& ) );
+SA( ! __is_invocable( memfun_type_i, A&, int ) );
+
+using memfun_type_ic = int (A::*)() const;
+
+SA( ! __is_invocable( memfun_type_ic ) );
+SA( ! __is_invocable( memfun_type_ic, int ) );
+SA( ! __is_invocable( memfun_type_ic, int& ) );
+SA( __is_invocable( memfun_type_ic, A& ) );
+SA( __is_invocable( memfun_type_ic, A* ) );
+SA( ! __is_invocable( memfun_type_ic, A&, int ) );
+SA( ! __is_invocable( memfun_type_ic, A*, int& ) );
+SA( __is_invocable( memfun_type_ic, const A& ) );
+SA( __is_invocable( memfun_type_ic, const A* ) );
+SA( ! __is_invocable( memfun_type_ic, const A&, int& ) );
+SA( ! __is_invocable( memfun_type_ic, const A*, int ) );
+
+using memfun_type_iic = int& (A::*)(int&) const;
+
+SA( ! __is_invocable( memfun_type_iic ) );
+SA( ! __is_invocable( memfun_type_iic, int ) );
+SA( ! __is_invocable( memfun_type_iic, int& ) );
+SA( ! __is_invocable( memfun_type_iic, A&, int ) );
+SA( __is_invocable( memfun_type_iic, A&, int& ) );
+SA( ! __is_invocable( memfun_type_iic, A*, int ) );
+SA( __is_invocable( memfun_type_iic, A*, int& ) );
+SA( ! __is_invocable( memfun_type_iic, const A&, int ) );
+SA( ! __is_invocable( memfun_type_iic, const A&, int&, int ) );
+SA( __is_invocable( memfun_type_iic, const A&, int& ) );
+SA( __is_invocable( memfun_type_iic, const A*, int& ) );
+
+struct B {
+ int& operator()();
+ long& operator()() const;
+ bool& operator()(int);
+private:
+ void operator()(int, int);
+};
+using CB = const B;
+
+SA( __is_invocable( B ) );
+SA( __is_invocable( B& ) );
+SA( __is_invocable( B&& ) );
+SA( ! __is_invocable( B* ) );
+SA( __is_invocable( CB ) );
+SA( __is_invocable( CB& ) );
+SA( ! __is_invocable( CB* ) );
+
+SA( __is_invocable( B, int ) );
+SA( __is_invocable( B&, int ) );
+SA( __is_invocable( B&&, int ) );
+SA( ! __is_invocable( B*, int ) );
+SA( ! __is_invocable( CB, int ) );
+SA( ! __is_invocable( CB&, int ) );
+SA( ! __is_invocable( CB*, int ) );
+
+SA( ! __is_invocable( B, int, int ) );
+SA( ! __is_invocable( B&, int, int ) );
+SA( ! __is_invocable( B&&, int, int ) );
+SA( ! __is_invocable( B*, int, int ) );
+SA( ! __is_invocable( CB, int, int ) );
+SA( ! __is_invocable( CB&, int, int ) );
+SA( ! __is_invocable( CB*, int, int ) );
+
+struct C : B { int& operator()() = delete; };
+using CC = const C;
+
+SA( ! __is_invocable( C ) );
+SA( ! __is_invocable( C& ) );
+SA( ! __is_invocable( C&& ) );
+SA( ! __is_invocable( C* ) );
+SA( ! __is_invocable( CC ) );
+SA( ! __is_invocable( CC& ) );
+SA( ! __is_invocable( CC* ) );
+
+struct D { B operator*(); };
+using CD = const D;
+
+SA( ! __is_invocable( D ) );
+
+struct E { void v(); };
+using CE = const E;
+
+SA( ! __is_invocable( E ) );
+SA( ! __is_invocable( void (E::*)() ) );
+SA( __is_invocable( void (E::*)(), E ) );
+SA( __is_invocable( void (E::*)(), E* ) );
+SA( ! __is_invocable( void (E::*)(), CE ) );
+
+struct F : E {};
+using CF = const F;
+
+SA( ! __is_invocable( F ) );
+SA( __is_invocable( void (E::*)(), F ) );
+SA( __is_invocable( void (E::*)(), F* ) );
+SA( ! __is_invocable( void (E::*)(), CF ) );
+
+struct G { E operator*(); };
+using CG = const G;
+
+SA( ! __is_invocable( G ) );
+SA( __is_invocable( void (E::*)(), G ) );
+SA( ! __is_invocable( void (E::*)(), G* ) );
+SA( ! __is_invocable( void (E::*)(), CG ) );
+
+struct H { E& operator*(); };
+using CH = const H;
+
+SA( ! __is_invocable( H ) );
+SA( __is_invocable( void (E::*)(), H ) );
+SA( ! __is_invocable( void (E::*)(), H* ) );
+SA( ! __is_invocable( void (E::*)(), CH ) );
+
+struct I { E&& operator*(); };
+using CI = const I;
+
+SA( ! __is_invocable( I ) );
+SA( __is_invocable( void (E::*)(), I ) );
+SA( ! __is_invocable( void (E::*)(), I* ) );
+SA( ! __is_invocable( void (E::*)(), CI ) );
+
+struct K { E* operator*(); };
+using CK = const K;
+
+SA( ! __is_invocable( K ) );
+SA( ! __is_invocable( void (E::*)(), K ) );
+SA( ! __is_invocable( void (E::*)(), K* ) );
+SA( ! __is_invocable( void (E::*)(), CK ) );
+
+struct L { CE operator*(); };
+using CL = const L;
+
+SA( ! __is_invocable( L ) );
+SA( ! __is_invocable( void (E::*)(), L ) );
+SA( ! __is_invocable( void (E::*)(), L* ) );
+SA( ! __is_invocable( void (E::*)(), CL ) );
+
+struct M {
+ int i;
+private:
+ long l;
+};
+using CM = const M;
+
+SA( ! __is_invocable( M ) );
+SA( ! __is_invocable( M& ) );
+SA( ! __is_invocable( M&& ) );
+SA( ! __is_invocable( M* ) );
+SA( ! __is_invocable( CM ) );
+SA( ! __is_invocable( CM& ) );
+SA( ! __is_invocable( CM* ) );
+
+SA( ! __is_invocable( int M::* ) );
+SA( __is_invocable( int M::*, M ) );
+SA( __is_invocable( int M::*, M& ) );
+SA( __is_invocable( int M::*, M&& ) );
+SA( __is_invocable( int M::*, M* ) );
+SA( __is_invocable( int M::*, CM ) );
+SA( __is_invocable( int M::*, CM& ) );
+SA( __is_invocable( int M::*, CM* ) );
+SA( ! __is_invocable( int M::*, int ) );
+
+SA( ! __is_invocable( int CM::* ) );
+SA( __is_invocable( int CM::*, M ) );
+SA( __is_invocable( int CM::*, M& ) );
+SA( __is_invocable( int CM::*, M&& ) );
+SA( __is_invocable( int CM::*, M* ) );
+SA( __is_invocable( int CM::*, CM ) );
+SA( __is_invocable( int CM::*, CM& ) );
+SA( __is_invocable( int CM::*, CM* ) );
+SA( ! __is_invocable( int CM::*, int ) );
+
+SA( ! __is_invocable( long M::* ) );
+SA( __is_invocable( long M::*, M ) );
+SA( __is_invocable( long M::*, M& ) );
+SA( __is_invocable( long M::*, M&& ) );
+SA( __is_invocable( long M::*, M* ) );
+SA( __is_invocable( long M::*, CM ) );
+SA( __is_invocable( long M::*, CM& ) );
+SA( __is_invocable( long M::*, CM* ) );
+SA( ! __is_invocable( long M::*, long ) );
+
+SA( ! __is_invocable( long CM::* ) );
+SA( __is_invocable( long CM::*, M ) );
+SA( __is_invocable( long CM::*, M& ) );
+SA( __is_invocable( long CM::*, M&& ) );
+SA( __is_invocable( long CM::*, M* ) );
+SA( __is_invocable( long CM::*, CM ) );
+SA( __is_invocable( long CM::*, CM& ) );
+SA( __is_invocable( long CM::*, CM* ) );
+SA( ! __is_invocable( long CM::*, long ) );
+
+SA( ! __is_invocable( short M::* ) );
+SA( __is_invocable( short M::*, M ) );
+SA( __is_invocable( short M::*, M& ) );
+SA( __is_invocable( short M::*, M&& ) );
+SA( __is_invocable( short M::*, M* ) );
+SA( __is_invocable( short M::*, CM ) );
+SA( __is_invocable( short M::*, CM& ) );
+SA( __is_invocable( short M::*, CM* ) );
+SA( ! __is_invocable( short M::*, short ) );
+
+SA( ! __is_invocable( short CM::* ) );
+SA( __is_invocable( short CM::*, M ) );
+SA( __is_invocable( short CM::*, M& ) );
+SA( __is_invocable( short CM::*, M&& ) );
+SA( __is_invocable( short CM::*, M* ) );
+SA( __is_invocable( short CM::*, CM ) );
+SA( __is_invocable( short CM::*, CM& ) );
+SA( __is_invocable( short CM::*, CM* ) );
+SA( ! __is_invocable( short CM::*, short ) );
+
+struct N { M operator*(); };
+SA( __is_invocable( int M::*, N ) );
+SA( ! __is_invocable( int M::*, N* ) );
+
+struct O { M& operator*(); };
+SA( __is_invocable( int M::*, O ) );
+SA( ! __is_invocable( int M::*, O* ) );
+
+struct P { M&& operator*(); };
+SA( __is_invocable( int M::*, P ) );
+SA( ! __is_invocable( int M::*, P* ) );
+
+struct Q { M* operator*(); };
+SA( ! __is_invocable( int M::*, Q ) );
+SA( ! __is_invocable( int M::*, Q* ) );
+
+struct R { void operator()(int = 0); };
+
+SA( __is_invocable( R ) );
+SA( __is_invocable( R, int ) );
+SA( ! __is_invocable( R, int, int ) );
+
+struct S { void operator()(int, ...); };
+
+SA( ! __is_invocable( S ) );
+SA( __is_invocable( S, int ) );
+SA( __is_invocable( S, int, int ) );
+SA( __is_invocable( S, int, int, int ) );
+
+void fn1() {}
+
+SA( __is_invocable( decltype(fn1) ) );
+
+void fn2(int arr[10]);
+
+SA( __is_invocable( decltype(fn2), int[10] ) );
+SA( __is_invocable( decltype(fn2), int(&)[10] ) );
+SA( __is_invocable( decltype(fn2), int(&&)[10] ) );
+SA( ! __is_invocable( decltype(fn2), int(*)[10] ) );
+SA( ! __is_invocable( decltype(fn2), int(*&)[10] ) );
+SA( ! __is_invocable( decltype(fn2), int(*&&)[10] ) );
+SA( __is_invocable( decltype(fn2), int[] ) );
+
+auto lambda = []() {};
+
+SA( __is_invocable( decltype(lambda) ) );
+
+template <typename Func, typename... Args>
+struct can_invoke {
+ static constexpr bool value = __is_invocable( Func, Args... );
+};
+
+SA( can_invoke<decltype(lambda)>::value );
+
+struct T {
+ void func() const {}
+ int data;
+};
+
+SA( __is_invocable( decltype(&T::func)&, T& ) );
+SA( __is_invocable( decltype(&T::data)&, T& ) );
+
+struct U { };
+struct V : U { U& operator*() = delete; };
+SA( __is_invocable( int U::*, V ) );
+
+struct W : private U { U& operator*(); };
+SA( ! __is_invocable( int U::*, W ) );
+
+struct X { int m; };
+struct Y { X& operator*(); };
+struct Z : Y { };
+SA( __is_invocable(int X::*, Z) );
new file mode 100644
@@ -0,0 +1,139 @@
+// { dg-do compile { target c++11 } }
+// __is_invocable should handle std::reference_wrapper correctly.
+
+#include <functional>
+
+#define SA(X) static_assert((X),#X)
+
+using std::reference_wrapper;
+
+using func_type_v0 = void(*)();
+
+SA( __is_invocable( reference_wrapper<func_type_v0> ) );
+SA( ! __is_invocable( reference_wrapper<func_type_v0>, int ) );
+
+using func_type_i0 = int(*)();
+
+SA( __is_invocable( reference_wrapper<func_type_i0> ) );
+SA( ! __is_invocable( reference_wrapper<func_type_i0>, int ) );
+
+using func_type_l0 = int&(*)();
+
+SA( __is_invocable( reference_wrapper<func_type_l0> ) );
+SA( ! __is_invocable( reference_wrapper<func_type_l0(int)> ) );
+
+using func_type_ii = int(*)(int);
+
+SA( ! __is_invocable( reference_wrapper<func_type_ii> ) );
+SA( __is_invocable( reference_wrapper<func_type_ii>, int ) );
+
+using func_type_il = int(*)(int&);
+
+SA( ! __is_invocable( reference_wrapper<func_type_il> ) );
+SA( ! __is_invocable( reference_wrapper<func_type_il>, int ) );
+SA( __is_invocable( reference_wrapper<func_type_il>, int& ) );
+
+using func_type_ir = int(*)(int&&);
+
+SA( ! __is_invocable( reference_wrapper<func_type_ir> ) );
+SA( ! __is_invocable( reference_wrapper<func_type_ir>, int& ) );
+SA( __is_invocable( reference_wrapper<func_type_ir>, int ) );
+SA( __is_invocable( reference_wrapper<func_type_ir>, int&& ) );
+
+struct A { };
+
+using mem_type_i = int A::*;
+
+SA( ! __is_invocable( reference_wrapper<mem_type_i> ) );
+SA( ! __is_invocable( reference_wrapper<mem_type_i>, int ) );
+SA( ! __is_invocable( reference_wrapper<mem_type_i>, int* ) );
+SA( ! __is_invocable( reference_wrapper<mem_type_i>, int& ) );
+SA( ! __is_invocable( reference_wrapper<mem_type_i>, int&& ) );
+SA( __is_invocable( reference_wrapper<mem_type_i>, A ) );
+SA( __is_invocable( reference_wrapper<mem_type_i>, A* ) );
+SA( __is_invocable( reference_wrapper<mem_type_i>, A& ) );
+SA( __is_invocable( reference_wrapper<mem_type_i>, A&& ) );
+
+using memfun_type_i = int (A::*)();
+
+SA( ! __is_invocable( reference_wrapper<memfun_type_i> ) );
+SA( ! __is_invocable( reference_wrapper<memfun_type_i>, int ) );
+SA( ! __is_invocable( reference_wrapper<memfun_type_i>, int* ) );
+SA( ! __is_invocable( reference_wrapper<memfun_type_i>, int& ) );
+SA( ! __is_invocable( reference_wrapper<memfun_type_i>, int&& ) );
+SA( __is_invocable( reference_wrapper<memfun_type_i>, A ) );
+SA( __is_invocable( reference_wrapper<memfun_type_i>, A* ) );
+SA( __is_invocable( reference_wrapper<memfun_type_i>, A& ) );
+SA( __is_invocable( reference_wrapper<memfun_type_i>, A&& ) );
+SA( ! __is_invocable( reference_wrapper<memfun_type_i>, const A& ) );
+SA( ! __is_invocable( reference_wrapper<memfun_type_i>, A&, int ) );
+
+using memfun_type_ic = int (A::*)() const;
+
+SA( ! __is_invocable( reference_wrapper<memfun_type_ic> ) );
+SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, int ) );
+SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, int& ) );
+SA( __is_invocable( reference_wrapper<memfun_type_ic>, A& ) );
+SA( __is_invocable( reference_wrapper<memfun_type_ic>, A* ) );
+SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, A&, int ) );
+SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, A*, int& ) );
+SA( __is_invocable( reference_wrapper<memfun_type_ic>, const A& ) );
+SA( __is_invocable( reference_wrapper<memfun_type_ic>, const A* ) );
+SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, const A&, int& ) );
+SA( ! __is_invocable( reference_wrapper<memfun_type_ic>, const A*, int ) );
+
+using memfun_type_iic = int& (A::*)(int&) const;
+
+SA( ! __is_invocable( reference_wrapper<memfun_type_iic> ) );
+SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, int ) );
+SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, int& ) );
+SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, A&, int ) );
+SA( __is_invocable( reference_wrapper<memfun_type_iic>, A&, int& ) );
+SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, A*, int ) );
+SA( __is_invocable( reference_wrapper<memfun_type_iic>, A*, int& ) );
+SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, const A&, int ) );
+SA( ! __is_invocable( reference_wrapper<memfun_type_iic>, const A&, int&, int ) );
+SA( __is_invocable( reference_wrapper<memfun_type_iic>, const A&, int& ) );
+SA( __is_invocable( reference_wrapper<memfun_type_iic>, const A*, int& ) );
+
+struct B {
+ int& operator()();
+ long& operator()() const;
+ bool& operator()(int);
+private:
+ void operator()(int, int);
+};
+using CB = const B;
+
+SA( __is_invocable( reference_wrapper<B> ) );
+SA( __is_invocable( reference_wrapper<B>& ) );
+SA( __is_invocable( reference_wrapper<B>&& ) );
+SA( __is_invocable( reference_wrapper<CB> ) );
+SA( __is_invocable( reference_wrapper<CB>& ) );
+SA( __is_invocable( reference_wrapper<B>, int ) );
+SA( ! __is_invocable( reference_wrapper<B>&, int, int ) );
+
+struct C : B { int& operator()() = delete; };
+using CC = const C;
+
+SA( ! __is_invocable( reference_wrapper<C> ) );
+SA( ! __is_invocable( reference_wrapper<C>& ) );
+SA( ! __is_invocable( reference_wrapper<C>&& ) );
+SA( ! __is_invocable( reference_wrapper<CC> ) );
+SA( ! __is_invocable( reference_wrapper<CC>& ) );
+
+struct D { B operator*(); };
+using CD = const D;
+
+SA( ! __is_invocable( reference_wrapper<D> ) );
+SA( ! __is_invocable( reference_wrapper<D>& ) );
+SA( ! __is_invocable( reference_wrapper<D>&& ) );
+SA( ! __is_invocable( reference_wrapper<D>* ) );
+SA( ! __is_invocable( reference_wrapper<D*> ) );
+SA( ! __is_invocable( reference_wrapper<D*>* ) );
+
+std::function<void()> fn = []() {};
+auto refwrap = std::ref(fn);
+
+SA( __is_invocable( decltype(fn) ) );
+SA( __is_invocable( decltype(refwrap) ) );
new file mode 100644
@@ -0,0 +1,51 @@
+// { dg-do compile { target c++11 } }
+// __is_invocable should handle incomplete class correctly.
+
+#define SA(X) static_assert((X),#X)
+
+struct Incomplete;
+
+SA( ! __is_invocable( Incomplete ) ); // { dg-error "incomplete type" }
+SA( ! __is_invocable( Incomplete, int ) ); // { dg-error "incomplete type" }
+
+SA( ! __is_invocable( int, Incomplete, int ) ); // { dg-error "incomplete type" }
+SA( ! __is_invocable( int, Incomplete ) ); // { dg-error "incomplete type" }
+
+SA( ! __is_invocable( Incomplete, Incomplete() ) ); // { dg-error "incomplete type" }
+SA( ! __is_invocable( Incomplete, Incomplete(int), int ) ); // { dg-error "incomplete type" }
+SA( ! __is_invocable( Incomplete, Incomplete(int, int), int, int ) ); // { dg-error "incomplete type" }
+
+SA( ! __is_invocable( Incomplete, Incomplete(), int, int ) ); // { dg-error "incomplete type" }
+
+SA( ! __is_invocable( int(Incomplete), Incomplete ) ); // { dg-error "incomplete type" }
+SA( ! __is_invocable( int(int, Incomplete), int, Incomplete ) ); // { dg-error "incomplete type" }
+SA( ! __is_invocable( int(int, Incomplete), Incomplete, int ) ); // { dg-error "incomplete type" }
+
+SA( __is_invocable( int(Incomplete&), Incomplete& ) ); // { dg-bogus "incomplete type" }
+SA( __is_invocable( int(int, Incomplete&), int, Incomplete& ) ); // { dg-bogus "incomplete type" }
+
+SA( __is_invocable( int(Incomplete&&), Incomplete&& ) ); // { dg-bogus "incomplete type" }
+SA( __is_invocable( int(int, Incomplete&&), int, Incomplete&& ) ); // { dg-bogus "incomplete type" }
+
+SA( __is_invocable( int(const Incomplete&&), const Incomplete&& ) ); // { dg-bogus "incomplete type" }
+SA( __is_invocable( int(int, const Incomplete&&), int, const Incomplete&& ) ); // { dg-bogus "incomplete type" }
+
+SA( __is_invocable( int(const Incomplete&), const Incomplete& ) ); // { dg-bogus "incomplete type" }
+SA( __is_invocable( int(int, const Incomplete&), int, const Incomplete& ) ); // { dg-bogus "incomplete type" }
+
+SA( __is_invocable( int(const Incomplete&), Incomplete& ) ); // { dg-bogus "incomplete type" }
+SA( __is_invocable( int(int, const Incomplete&), int, Incomplete& ) ); // { dg-bogus "incomplete type" }
+
+SA( __is_invocable( int Incomplete::*, const Incomplete& ) ); // { dg-bogus "incomplete type" }
+SA( ! __is_invocable( void (Incomplete::*)(long&), const Incomplete*, long& ) ); // { dg-bogus "incomplete type" }
+SA( __is_invocable( void (Incomplete::*)(long&) const, Incomplete*, long& ) ); // { dg-bogus "incomplete type" }
+
+template <typename T>
+struct Holder { T t; };
+
+SA( __is_invocable( int(Holder<Incomplete>&), Holder<Incomplete>& ) ); // { dg-bogus "incomplete type" }
+
+// Define Incomplete, which is now not incomplete.
+struct Incomplete { void operator()(); };
+
+SA( __is_invocable( Incomplete ) ); // { dg-bogus "incomplete type" }
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@@ -0,0 +1,33 @@
+// { dg-do compile { target c++11 } }
+// Failed access check should be a substitution failure, not an error.
+
+#define SA(X) static_assert((X),#X)
+
+template<bool B>
+struct bool_constant { static constexpr bool value = B; };
+
+template<typename _Fn, typename... _ArgTypes>
+struct is_invocable
+: public bool_constant<__is_invocable(_Fn, _ArgTypes...)>
+{ };
+
+#if __cpp_variable_templates
+template<typename _Fn, typename... _ArgTypes>
+constexpr bool is_invocable_v = __is_invocable(_Fn, _ArgTypes...);
+#endif
+
+class Private
+{
+ void operator()() const
+ {
+ SA( ! is_invocable<Private>::value );
+#if __cpp_variable_templates
+ SA( ! is_invocable_v<Private> );
+#endif
+ }
+};
+
+SA( ! is_invocable<Private>::value );
+#if __cpp_variable_templates
+SA( ! is_invocable_v<Private> );
+#endif